/* * QEMU PowerPC 4xx embedded processors shared devices emulation * * Copyright (c) 2007 Jocelyn Mayer * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "hw.h" #include "ppc.h" #include "ppc4xx.h" #include "sysemu.h" #include "qemu-log.h" //#define DEBUG_MMIO //#define DEBUG_UNASSIGNED #define DEBUG_UIC #ifdef DEBUG_UIC # define LOG_UIC(...) qemu_log_mask(CPU_LOG_INT, ## __VA_ARGS__) #else # define LOG_UIC(...) do { } while (0) #endif /*****************************************************************************/ /* Generic PowerPC 4xx processor instanciation */ CPUState *ppc4xx_init (const char *cpu_model, clk_setup_t *cpu_clk, clk_setup_t *tb_clk, uint32_t sysclk) { CPUState *env; /* init CPUs */ env = cpu_init(cpu_model); if (!env) { fprintf(stderr, "Unable to find PowerPC %s CPU definition\n", cpu_model); exit(1); } cpu_clk->cb = NULL; /* We don't care about CPU clock frequency changes */ cpu_clk->opaque = env; /* Set time-base frequency to sysclk */ tb_clk->cb = ppc_emb_timers_init(env, sysclk); tb_clk->opaque = env; ppc_dcr_init(env, NULL, NULL); /* Register qemu callbacks */ qemu_register_reset(&cpu_ppc_reset, env); return env; } /*****************************************************************************/ /* "Universal" Interrupt controller */ enum { DCR_UICSR = 0x000, DCR_UICSRS = 0x001, DCR_UICER = 0x002, DCR_UICCR = 0x003, DCR_UICPR = 0x004, DCR_UICTR = 0x005, DCR_UICMSR = 0x006, DCR_UICVR = 0x007, DCR_UICVCR = 0x008, DCR_UICMAX = 0x009, }; #define UIC_MAX_IRQ 32 typedef struct ppcuic_t ppcuic_t; struct ppcuic_t { uint32_t dcr_base; int use_vectors; uint32_t level; /* Remembers the state of level-triggered interrupts. */ uint32_t uicsr; /* Status register */ uint32_t uicer; /* Enable register */ uint32_t uiccr; /* Critical register */ uint32_t uicpr; /* Polarity register */ uint32_t uictr; /* Triggering register */ uint32_t uicvcr; /* Vector configuration register */ uint32_t uicvr; qemu_irq *irqs; }; static void ppcuic_trigger_irq (ppcuic_t *uic) { uint32_t ir, cr; int start, end, inc, i; /* Trigger interrupt if any is pending */ ir = uic->uicsr & uic->uicer & (~uic->uiccr); cr = uic->uicsr & uic->uicer & uic->uiccr; LOG_UIC("%s: uicsr %08" PRIx32 " uicer %08" PRIx32 " uiccr %08" PRIx32 "\n" " %08" PRIx32 " ir %08" PRIx32 " cr %08" PRIx32 "\n", __func__, uic->uicsr, uic->uicer, uic->uiccr, uic->uicsr & uic->uicer, ir, cr); if (ir != 0x0000000) { LOG_UIC("Raise UIC interrupt\n"); qemu_irq_raise(uic->irqs[PPCUIC_OUTPUT_INT]); } else { LOG_UIC("Lower UIC interrupt\n"); qemu_irq_lower(uic->irqs[PPCUIC_OUTPUT_INT]); } /* Trigger critical interrupt if any is pending and update vector */ if (cr != 0x0000000) { qemu_irq_raise(uic->irqs[PPCUIC_OUTPUT_CINT]); if (uic->use_vectors) { /* Compute critical IRQ vector */ if (uic->uicvcr & 1) { start = 31; end = 0; inc = -1; } else { start = 0; end = 31; inc = 1; } uic->uicvr = uic->uicvcr & 0xFFFFFFFC; for (i = start; i <= end; i += inc) { if (cr & (1 << i)) { uic->uicvr += (i - start) * 512 * inc; break; } } } LOG_UIC("Raise UIC critical interrupt - " "vector %08" PRIx32 "\n", uic->uicvr); } else { LOG_UIC("Lower UIC critical interrupt\n"); qemu_irq_lower(uic->irqs[PPCUIC_OUTPUT_CINT]); uic->uicvr = 0x00000000; } } static void ppcuic_set_irq (void *opaque, int irq_num, int level) { ppcuic_t *uic; uint32_t mask, sr; uic = opaque; mask = 1 << (31-irq_num); LOG_UIC("%s: irq %d level %d uicsr %08" PRIx32 " mask %08" PRIx32 " => %08" PRIx32 " %08" PRIx32 "\n", __func__, irq_num, level, uic->uicsr, mask, uic->uicsr & mask, level << irq_num); if (irq_num < 0 || irq_num > 31) return; sr = uic->uicsr; /* Update status register */ if (uic->uictr & mask) { /* Edge sensitive interrupt */ if (level == 1) uic->uicsr |= mask; } else { /* Level sensitive interrupt */ if (level == 1) { uic->uicsr |= mask; uic->level |= mask; } else { uic->uicsr &= ~mask; uic->level &= ~mask; } } LOG_UIC("%s: irq %d level %d sr %" PRIx32 " => " "%08" PRIx32 "\n", __func__, irq_num, level, uic->uicsr, sr); if (sr != uic->uicsr) ppcuic_trigger_irq(uic); } static target_ulong dcr_read_uic (void *opaque, int dcrn) { ppcuic_t *uic; target_ulong ret; uic = opaque; dcrn -= uic->dcr_base; switch (dcrn) { case DCR_UICSR: case DCR_UICSRS: ret = uic->uicsr; break; case DCR_UICER: ret = uic->uicer; break; case DCR_UICCR: ret = uic->uiccr; break; case DCR_UICPR: ret = uic->uicpr; break; case DCR_UICTR: ret = uic->uictr; break; case DCR_UICMSR: ret = uic->uicsr & uic->uicer; break; case DCR_UICVR: if (!uic->use_vectors) goto no_read; ret = uic->uicvr; break; case DCR_UICVCR: if (!uic->use_vectors) goto no_read; ret = uic->uicvcr; break; default: no_read: ret = 0x00000000; break; } return ret; } static void dcr_write_uic (void *opaque, int dcrn, target_ulong val) { ppcuic_t *uic; uic = opaque; dcrn -= uic->dcr_base; LOG_UIC("%s: dcr %d val " ADDRX "\n", __func__, dcrn, val); switch (dcrn) { case DCR_UICSR: uic->uicsr &= ~val; uic->uicsr |= uic->level; ppcuic_trigger_irq(uic); break; case DCR_UICSRS: uic->uicsr |= val; ppcuic_trigger_irq(uic); break; case DCR_UICER: uic->uicer = val; ppcuic_trigger_irq(uic); break; case DCR_UICCR: uic->uiccr = val; ppcuic_trigger_irq(uic); break; case DCR_UICPR: uic->uicpr = val; break; case DCR_UICTR: uic->uictr = val; ppcuic_trigger_irq(uic); break; case DCR_UICMSR: break; case DCR_UICVR: break; case DCR_UICVCR: uic->uicvcr = val & 0xFFFFFFFD; ppcuic_trigger_irq(uic); break; } } static void ppcuic_reset (void *opaque) { ppcuic_t *uic; uic = opaque; uic->uiccr = 0x00000000; uic->uicer = 0x00000000; uic->uicpr = 0x00000000; uic->uicsr = 0x00000000; uic->uictr = 0x00000000; if (uic->use_vectors) { uic->uicvcr = 0x00000000; uic->uicvr = 0x0000000; } } qemu_irq *ppcuic_init (CPUState *env, qemu_irq *irqs, uint32_t dcr_base, int has_ssr, int has_vr) { ppcuic_t *uic; int i; uic = qemu_mallocz(sizeof(ppcuic_t)); uic->dcr_base = dcr_base; uic->irqs = irqs; if (has_vr) uic->use_vectors = 1; for (i = 0; i < DCR_UICMAX; i++) { ppc_dcr_register(env, dcr_base + i, uic, &dcr_read_uic, &dcr_write_uic); } qemu_register_reset(ppcuic_reset, uic); ppcuic_reset(uic); return qemu_allocate_irqs(&ppcuic_set_irq, uic, UIC_MAX_IRQ); } /*****************************************************************************/ /* SDRAM controller */ typedef struct ppc4xx_sdram_t ppc4xx_sdram_t; struct ppc4xx_sdram_t { uint32_t addr; int nbanks; target_phys_addr_t ram_bases[4]; target_phys_addr_t ram_sizes[4]; uint32_t besr0; uint32_t besr1; uint32_t bear; uint32_t cfg; uint32_t status; uint32_t rtr; uint32_t pmit; uint32_t bcr[4]; uint32_t tr; uint32_t ecccfg; uint32_t eccesr; qemu_irq irq; }; enum { SDRAM0_CFGADDR = 0x010, SDRAM0_CFGDATA = 0x011, }; /* XXX: TOFIX: some patches have made this code become inconsistent: * there are type inconsistencies, mixing target_phys_addr_t, target_ulong * and uint32_t */ static uint32_t sdram_bcr (target_phys_addr_t ram_base, target_phys_addr_t ram_size) { uint32_t bcr; switch (ram_size) { case (4 * 1024 * 1024): bcr = 0x00000000; break; case (8 * 1024 * 1024): bcr = 0x00020000; break; case (16 * 1024 * 1024): bcr = 0x00040000; break; case (32 * 1024 * 1024): bcr = 0x00060000; break; case (64 * 1024 * 1024): bcr = 0x00080000; break; case (128 * 1024 * 1024): bcr = 0x000A0000; break; case (256 * 1024 * 1024): bcr = 0x000C0000; break; default: printf("%s: invalid RAM size " PADDRX "\n", __func__, ram_size); return 0x00000000; } bcr |= ram_base & 0xFF800000; bcr |= 1; return bcr; } static always_inline target_phys_addr_t sdram_base (uint32_t bcr) { return bcr & 0xFF800000; } static target_ulong sdram_size (uint32_t bcr) { target_ulong size; int sh; sh = (bcr >> 17) & 0x7; if (sh == 7) size = -1; else size = (4 * 1024 * 1024) << sh; return size; } static void sdram_set_bcr (uint32_t *bcrp, uint32_t bcr, int enabled) { if (*bcrp & 0x00000001) { /* Unmap RAM */ #ifdef DEBUG_SDRAM printf("%s: unmap RAM area " PADDRX " " ADDRX "\n", __func__, sdram_base(*bcrp), sdram_size(*bcrp)); #endif cpu_register_physical_memory(sdram_base(*bcrp), sdram_size(*bcrp), IO_MEM_UNASSIGNED); } *bcrp = bcr & 0xFFDEE001; if (enabled && (bcr & 0x00000001)) { #ifdef DEBUG_SDRAM printf("%s: Map RAM area " PADDRX " " ADDRX "\n", __func__, sdram_base(bcr), sdram_size(bcr)); #endif cpu_register_physical_memory(sdram_base(bcr), sdram_size(bcr), sdram_base(bcr) | IO_MEM_RAM); } } static void sdram_map_bcr (ppc4xx_sdram_t *sdram) { int i; for (i = 0; i < sdram->nbanks; i++) { if (sdram->ram_sizes[i] != 0) { sdram_set_bcr(&sdram->bcr[i], sdram_bcr(sdram->ram_bases[i], sdram->ram_sizes[i]), 1); } else { sdram_set_bcr(&sdram->bcr[i], 0x00000000, 0); } } } static void sdram_unmap_bcr (ppc4xx_sdram_t *sdram) { int i; for (i = 0; i < sdram->nbanks; i++) { #ifdef DEBUG_SDRAM printf("%s: Unmap RAM area " PADDRX " " ADDRX "\n", __func__, sdram_base(sdram->bcr[i]), sdram_size(sdram->bcr[i])); #endif cpu_register_physical_memory(sdram_base(sdram->bcr[i]), sdram_size(sdram->bcr[i]), IO_MEM_UNASSIGNED); } } static target_ulong dcr_read_sdram (void *opaque, int dcrn) { ppc4xx_sdram_t *sdram; target_ulong ret; sdram = opaque; switch (dcrn) { case SDRAM0_CFGADDR: ret = sdram->addr; break; case SDRAM0_CFGDATA: switch (sdram->addr) { case 0x00: /* SDRAM_BESR0 */ ret = sdram->besr0; break; case 0x08: /* SDRAM_BESR1 */ ret = sdram->besr1; break; case 0x10: /* SDRAM_BEAR */ ret = sdram->bear; break; case 0x20: /* SDRAM_CFG */ ret = sdram->cfg; break; case 0x24: /* SDRAM_STATUS */ ret = sdram->status; break; case 0x30: /* SDRAM_RTR */ ret = sdram->rtr; break; case 0x34: /* SDRAM_PMIT */ ret = sdram->pmit; break; case 0x40: /* SDRAM_B0CR */ ret = sdram->bcr[0]; break; case 0x44: /* SDRAM_B1CR */ ret = sdram->bcr[1]; break; case 0x48: /* SDRAM_B2CR */ ret = sdram->bcr[2]; break; case 0x4C: /* SDRAM_B3CR */ ret = sdram->bcr[3]; break; case 0x80: /* SDRAM_TR */ ret = -1; /* ? */ break; case 0x94: /* SDRAM_ECCCFG */ ret = sdram->ecccfg; break; case 0x98: /* SDRAM_ECCESR */ ret = sdram->eccesr; break; default: /* Error */ ret = -1; break; } break; default: /* Avoid gcc warning */ ret = 0x00000000; break; } return ret; } static void dcr_write_sdram (void *opaque, int dcrn, target_ulong val) { ppc4xx_sdram_t *sdram; sdram = opaque; switch (dcrn) { case SDRAM0_CFGADDR: sdram->addr = val; break; case SDRAM0_CFGDATA: switch (sdram->addr) { case 0x00: /* SDRAM_BESR0 */ sdram->besr0 &= ~val; break; case 0x08: /* SDRAM_BESR1 */ sdram->besr1 &= ~val; break; case 0x10: /* SDRAM_BEAR */ sdram->bear = val; break; case 0x20: /* SDRAM_CFG */ val &= 0xFFE00000; if (!(sdram->cfg & 0x80000000) && (val & 0x80000000)) { #ifdef DEBUG_SDRAM printf("%s: enable SDRAM controller\n", __func__); #endif /* validate all RAM mappings */ sdram_map_bcr(sdram); sdram->status &= ~0x80000000; } else if ((sdram->cfg & 0x80000000) && !(val & 0x80000000)) { #ifdef DEBUG_SDRAM printf("%s: disable SDRAM controller\n", __func__); #endif /* invalidate all RAM mappings */ sdram_unmap_bcr(sdram); sdram->status |= 0x80000000; } if (!(sdram->cfg & 0x40000000) && (val & 0x40000000)) sdram->status |= 0x40000000; else if ((sdram->cfg & 0x40000000) && !(val & 0x40000000)) sdram->status &= ~0x40000000; sdram->cfg = val; break; case 0x24: /* SDRAM_STATUS */ /* Read-only register */ break; case 0x30: /* SDRAM_RTR */ sdram->rtr = val & 0x3FF80000; break; case 0x34: /* SDRAM_PMIT */ sdram->pmit = (val & 0xF8000000) | 0x07C00000; break; case 0x40: /* SDRAM_B0CR */ sdram_set_bcr(&sdram->bcr[0], val, sdram->cfg & 0x80000000); break; case 0x44: /* SDRAM_B1CR */ sdram_set_bcr(&sdram->bcr[1], val, sdram->cfg & 0x80000000); break; case 0x48: /* SDRAM_B2CR */ sdram_set_bcr(&sdram->bcr[2], val, sdram->cfg & 0x80000000); break; case 0x4C: /* SDRAM_B3CR */ sdram_set_bcr(&sdram->bcr[3], val, sdram->cfg & 0x80000000); break; case 0x80: /* SDRAM_TR */ sdram->tr = val & 0x018FC01F; break; case 0x94: /* SDRAM_ECCCFG */ sdram->ecccfg = val & 0x00F00000; break; case 0x98: /* SDRAM_ECCESR */ val &= 0xFFF0F000; if (sdram->eccesr == 0 && val != 0) qemu_irq_raise(sdram->irq); else if (sdram->eccesr != 0 && val == 0) qemu_irq_lower(sdram->irq); sdram->eccesr = val; break; default: /* Error */ break; } break; } } static void sdram_reset (void *opaque) { ppc4xx_sdram_t *sdram; sdram = opaque; sdram->addr = 0x00000000; sdram->bear = 0x00000000; sdram->besr0 = 0x00000000; /* No error */ sdram->besr1 = 0x00000000; /* No error */ sdram->cfg = 0x00000000; sdram->ecccfg = 0x00000000; /* No ECC */ sdram->eccesr = 0x00000000; /* No error */ sdram->pmit = 0x07C00000; sdram->rtr = 0x05F00000; sdram->tr = 0x00854009; /* We pre-initialize RAM banks */ sdram->status = 0x00000000; sdram->cfg = 0x00800000; sdram_unmap_bcr(sdram); } void ppc4xx_sdram_init (CPUState *env, qemu_irq irq, int nbanks, target_phys_addr_t *ram_bases, target_phys_addr_t *ram_sizes, int do_init) { ppc4xx_sdram_t *sdram; sdram = qemu_mallocz(sizeof(ppc4xx_sdram_t)); sdram->irq = irq; sdram->nbanks = nbanks; memset(sdram->ram_bases, 0, 4 * sizeof(target_phys_addr_t)); memcpy(sdram->ram_bases, ram_bases, nbanks * sizeof(target_phys_addr_t)); memset(sdram->ram_sizes, 0, 4 * sizeof(target_phys_addr_t)); memcpy(sdram->ram_sizes, ram_sizes, nbanks * sizeof(target_phys_addr_t)); sdram_reset(sdram); qemu_register_reset(&sdram_reset, sdram); ppc_dcr_register(env, SDRAM0_CFGADDR, sdram, &dcr_read_sdram, &dcr_write_sdram); ppc_dcr_register(env, SDRAM0_CFGDATA, sdram, &dcr_read_sdram, &dcr_write_sdram); if (do_init) sdram_map_bcr(sdram); } /* Fill in consecutive SDRAM banks with 'ram_size' bytes of memory. * * sdram_bank_sizes[] must be 0-terminated. * * The 4xx SDRAM controller supports a small number of banks, and each bank * must be one of a small set of sizes. The number of banks and the supported * sizes varies by SoC. */ ram_addr_t ppc4xx_sdram_adjust(ram_addr_t ram_size, int nr_banks, target_phys_addr_t ram_bases[], target_phys_addr_t ram_sizes[], const unsigned int sdram_bank_sizes[]) { ram_addr_t size_left = ram_size; int i; int j; for (i = 0; i < nr_banks; i++) { for (j = 0; sdram_bank_sizes[j] != 0; j++) { unsigned int bank_size = sdram_bank_sizes[j]; if (bank_size <= size_left) { ram_bases[i] = qemu_ram_alloc(bank_size); ram_sizes[i] = bank_size; size_left -= bank_size; break; } } if (!size_left) { /* No need to use the remaining banks. */ break; } } ram_size -= size_left; if (ram_size) printf("Truncating memory to %d MiB to fit SDRAM controller limits.\n", (int)(ram_size >> 20)); return ram_size; }