/* * Copyright 2010 Tilera Corporation. All Rights Reserved. * * 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, version 2. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or * NON INFRINGEMENT. See the GNU General Public License for * more details. */ #include #include #include #include #include void __flush_icache_range(unsigned long start, unsigned long end) { invalidate_icache((const void *)start, end - start, PAGE_SIZE); } /* Force a load instruction to issue. */ static inline void force_load(char *p) { *(volatile char *)p; } /* * Flush and invalidate a VA range that is homed remotely on a single * core (if "!hfh") or homed via hash-for-home (if "hfh"), waiting * until the memory controller holds the flushed values. */ void finv_buffer_remote(void *buffer, size_t size, int hfh) { char *p, *base; size_t step_size, load_count; /* * On TILEPro the striping granularity is a fixed 8KB; on * TILE-Gx it is configurable, and we rely on the fact that * the hypervisor always configures maximum striping, so that * bits 9 and 10 of the PA are part of the stripe function, so * every 512 bytes we hit a striping boundary. * */ #ifdef __tilegx__ const unsigned long STRIPE_WIDTH = 512; #else const unsigned long STRIPE_WIDTH = 8192; #endif #ifdef __tilegx__ /* * On TILE-Gx, we must disable the dstream prefetcher before doing * a cache flush; otherwise, we could end up with data in the cache * that we don't want there. Note that normally we'd do an mf * after the SPR write to disabling the prefetcher, but we do one * below, before any further loads, so there's no need to do it * here. */ uint_reg_t old_dstream_pf = __insn_mfspr(SPR_DSTREAM_PF); __insn_mtspr(SPR_DSTREAM_PF, 0); #endif /* * Flush and invalidate the buffer out of the local L1/L2 * and request the home cache to flush and invalidate as well. */ __finv_buffer(buffer, size); /* * Wait for the home cache to acknowledge that it has processed * all the flush-and-invalidate requests. This does not mean * that the flushed data has reached the memory controller yet, * but it does mean the home cache is processing the flushes. */ __insn_mf(); /* * Issue a load to the last cache line, which can't complete * until all the previously-issued flushes to the same memory * controller have also completed. If we weren't striping * memory, that one load would be sufficient, but since we may * be, we also need to back up to the last load issued to * another memory controller, which would be the point where * we crossed a "striping" boundary (the granularity of striping * across memory controllers). Keep backing up and doing this * until we are before the beginning of the buffer, or have * hit all the controllers. * * If we are flushing a hash-for-home buffer, it's even worse. * Each line may be homed on a different tile, and each tile * may have up to four lines that are on different * controllers. So as we walk backwards, we have to touch * enough cache lines to satisfy these constraints. In * practice this ends up being close enough to "load from * every cache line on a full memory stripe on each * controller" that we simply do that, to simplify the logic. * * On TILE-Gx the hash-for-home function is much more complex, * with the upshot being we can't readily guarantee we have * hit both entries in the 128-entry AMT that were hit by any * load in the entire range, so we just re-load them all. * With larger buffers, we may want to consider using a hypervisor * trap to issue loads directly to each hash-for-home tile for * each controller (doing it from Linux would trash the TLB). */ if (hfh) { step_size = L2_CACHE_BYTES; #ifdef __tilegx__ load_count = (size + L2_CACHE_BYTES - 1) / L2_CACHE_BYTES; #else load_count = (STRIPE_WIDTH / L2_CACHE_BYTES) * (1 << CHIP_LOG_NUM_MSHIMS()); #endif } else { step_size = STRIPE_WIDTH; load_count = (1 << CHIP_LOG_NUM_MSHIMS()); } /* Load the last byte of the buffer. */ p = (char *)buffer + size - 1; force_load(p); /* Bump down to the end of the previous stripe or cache line. */ p -= step_size; p = (char *)((unsigned long)p | (step_size - 1)); /* Figure out how far back we need to go. */ base = p - (step_size * (load_count - 2)); if ((unsigned long)base < (unsigned long)buffer) base = buffer; /* * Fire all the loads we need. The MAF only has eight entries * so we can have at most eight outstanding loads, so we * unroll by that amount. */ #pragma unroll 8 for (; p >= base; p -= step_size) force_load(p); /* * Repeat, but with finv's instead of loads, to get rid of the * data we just loaded into our own cache and the old home L3. * No need to unroll since finv's don't target a register. * The finv's are guaranteed not to actually flush the data in * the buffer back to their home, since we just read it, so the * lines are clean in cache; we will only invalidate those lines. */ p = (char *)buffer + size - 1; __insn_finv(p); p -= step_size; p = (char *)((unsigned long)p | (step_size - 1)); for (; p >= base; p -= step_size) __insn_finv(p); /* Wait for these finv's (and thus the first finvs) to be done. */ __insn_mf(); #ifdef __tilegx__ /* Reenable the prefetcher. */ __insn_mtspr(SPR_DSTREAM_PF, old_dstream_pf); #endif } EXPORT_SYMBOL_GPL(finv_buffer_remote);