mirror of
https://github.com/AuxXxilium/linux_dsm_epyc7002.git
synced 2024-12-23 11:29:53 +07:00
855a95e4fc
This replaces all the pll_types definitions for ones that match the types used in the tables in recent VBIOS versions. get_pll_limits() will now accept either type or register value as input across all limits table versions, and will store the actual register ID that a PLL type refers to in the returned structure. Signed-off-by: Ben Skeggs <bskeggs@redhat.com>
479 lines
13 KiB
C
479 lines
13 KiB
C
/*
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* Copyright 1993-2003 NVIDIA, Corporation
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* Copyright 2007-2009 Stuart Bennett
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*
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* Permission is hereby granted, free of charge, to any person obtaining a
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* copy of this software and associated documentation files (the "Software"),
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* to deal in the Software without restriction, including without limitation
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* the rights to use, copy, modify, merge, publish, distribute, sublicense,
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* and/or sell copies of the Software, and to permit persons to whom the
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* Software is furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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* THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
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* WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF
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* OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
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* SOFTWARE.
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*/
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#include "drmP.h"
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#include "nouveau_drv.h"
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#include "nouveau_hw.h"
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/****************************************************************************\
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* *
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* The video arbitration routines calculate some "magic" numbers. Fixes *
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* the snow seen when accessing the framebuffer without it. *
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* It just works (I hope). *
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* *
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\****************************************************************************/
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struct nv_fifo_info {
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int lwm;
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int burst;
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};
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struct nv_sim_state {
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int pclk_khz;
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int mclk_khz;
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int nvclk_khz;
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int bpp;
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int mem_page_miss;
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int mem_latency;
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int memory_type;
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int memory_width;
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int two_heads;
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};
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static void
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nv04_calc_arb(struct nv_fifo_info *fifo, struct nv_sim_state *arb)
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{
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int pagemiss, cas, width, bpp;
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int nvclks, mclks, pclks, crtpagemiss;
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int found, mclk_extra, mclk_loop, cbs, m1, p1;
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int mclk_freq, pclk_freq, nvclk_freq;
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int us_m, us_n, us_p, crtc_drain_rate;
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int cpm_us, us_crt, clwm;
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pclk_freq = arb->pclk_khz;
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mclk_freq = arb->mclk_khz;
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nvclk_freq = arb->nvclk_khz;
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pagemiss = arb->mem_page_miss;
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cas = arb->mem_latency;
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width = arb->memory_width >> 6;
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bpp = arb->bpp;
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cbs = 128;
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pclks = 2;
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nvclks = 10;
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mclks = 13 + cas;
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mclk_extra = 3;
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found = 0;
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while (!found) {
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found = 1;
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mclk_loop = mclks + mclk_extra;
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us_m = mclk_loop * 1000 * 1000 / mclk_freq;
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us_n = nvclks * 1000 * 1000 / nvclk_freq;
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us_p = nvclks * 1000 * 1000 / pclk_freq;
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crtc_drain_rate = pclk_freq * bpp / 8;
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crtpagemiss = 2;
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crtpagemiss += 1;
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cpm_us = crtpagemiss * pagemiss * 1000 * 1000 / mclk_freq;
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us_crt = cpm_us + us_m + us_n + us_p;
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clwm = us_crt * crtc_drain_rate / (1000 * 1000);
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clwm++;
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m1 = clwm + cbs - 512;
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p1 = m1 * pclk_freq / mclk_freq;
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p1 = p1 * bpp / 8;
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if ((p1 < m1 && m1 > 0) || clwm > 519) {
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found = !mclk_extra;
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mclk_extra--;
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}
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if (clwm < 384)
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clwm = 384;
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fifo->lwm = clwm;
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fifo->burst = cbs;
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}
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}
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static void
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nv10_calc_arb(struct nv_fifo_info *fifo, struct nv_sim_state *arb)
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{
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int fill_rate, drain_rate;
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int pclks, nvclks, mclks, xclks;
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int pclk_freq, nvclk_freq, mclk_freq;
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int fill_lat, extra_lat;
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int max_burst_o, max_burst_l;
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int fifo_len, min_lwm, max_lwm;
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const int burst_lat = 80; /* Maximum allowable latency due
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* to the CRTC FIFO burst. (ns) */
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pclk_freq = arb->pclk_khz;
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nvclk_freq = arb->nvclk_khz;
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mclk_freq = arb->mclk_khz;
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fill_rate = mclk_freq * arb->memory_width / 8; /* kB/s */
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drain_rate = pclk_freq * arb->bpp / 8; /* kB/s */
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fifo_len = arb->two_heads ? 1536 : 1024; /* B */
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/* Fixed FIFO refill latency. */
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pclks = 4; /* lwm detect. */
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nvclks = 3 /* lwm -> sync. */
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+ 2 /* fbi bus cycles (1 req + 1 busy) */
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+ 1 /* 2 edge sync. may be very close to edge so
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* just put one. */
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+ 1 /* fbi_d_rdv_n */
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+ 1 /* Fbi_d_rdata */
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+ 1; /* crtfifo load */
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mclks = 1 /* 2 edge sync. may be very close to edge so
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* just put one. */
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+ 1 /* arb_hp_req */
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+ 5 /* tiling pipeline */
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+ 2 /* latency fifo */
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+ 2 /* memory request to fbio block */
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+ 7; /* data returned from fbio block */
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/* Need to accumulate 256 bits for read */
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mclks += (arb->memory_type == 0 ? 2 : 1)
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* arb->memory_width / 32;
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fill_lat = mclks * 1000 * 1000 / mclk_freq /* minimum mclk latency */
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+ nvclks * 1000 * 1000 / nvclk_freq /* nvclk latency */
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+ pclks * 1000 * 1000 / pclk_freq; /* pclk latency */
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/* Conditional FIFO refill latency. */
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xclks = 2 * arb->mem_page_miss + mclks /* Extra latency due to
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* the overlay. */
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+ 2 * arb->mem_page_miss /* Extra pagemiss latency. */
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+ (arb->bpp == 32 ? 8 : 4); /* Margin of error. */
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extra_lat = xclks * 1000 * 1000 / mclk_freq;
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if (arb->two_heads)
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/* Account for another CRTC. */
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extra_lat += fill_lat + extra_lat + burst_lat;
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/* FIFO burst */
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/* Max burst not leading to overflows. */
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max_burst_o = (1 + fifo_len - extra_lat * drain_rate / (1000 * 1000))
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* (fill_rate / 1000) / ((fill_rate - drain_rate) / 1000);
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fifo->burst = min(max_burst_o, 1024);
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/* Max burst value with an acceptable latency. */
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max_burst_l = burst_lat * fill_rate / (1000 * 1000);
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fifo->burst = min(max_burst_l, fifo->burst);
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fifo->burst = rounddown_pow_of_two(fifo->burst);
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/* FIFO low watermark */
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min_lwm = (fill_lat + extra_lat) * drain_rate / (1000 * 1000) + 1;
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max_lwm = fifo_len - fifo->burst
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+ fill_lat * drain_rate / (1000 * 1000)
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+ fifo->burst * drain_rate / fill_rate;
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fifo->lwm = min_lwm + 10 * (max_lwm - min_lwm) / 100; /* Empirical. */
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}
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static void
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nv04_update_arb(struct drm_device *dev, int VClk, int bpp,
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int *burst, int *lwm)
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{
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struct drm_nouveau_private *dev_priv = dev->dev_private;
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struct nv_fifo_info fifo_data;
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struct nv_sim_state sim_data;
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int MClk = nouveau_hw_get_clock(dev, PLL_MEMORY);
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int NVClk = nouveau_hw_get_clock(dev, PLL_CORE);
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uint32_t cfg1 = nvReadFB(dev, NV04_PFB_CFG1);
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sim_data.pclk_khz = VClk;
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sim_data.mclk_khz = MClk;
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sim_data.nvclk_khz = NVClk;
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sim_data.bpp = bpp;
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sim_data.two_heads = nv_two_heads(dev);
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if ((dev->pci_device & 0xffff) == 0x01a0 /*CHIPSET_NFORCE*/ ||
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(dev->pci_device & 0xffff) == 0x01f0 /*CHIPSET_NFORCE2*/) {
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uint32_t type;
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pci_read_config_dword(pci_get_bus_and_slot(0, 1), 0x7c, &type);
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sim_data.memory_type = (type >> 12) & 1;
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sim_data.memory_width = 64;
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sim_data.mem_latency = 3;
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sim_data.mem_page_miss = 10;
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} else {
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sim_data.memory_type = nvReadFB(dev, NV04_PFB_CFG0) & 0x1;
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sim_data.memory_width = (nvReadEXTDEV(dev, NV_PEXTDEV_BOOT_0) & 0x10) ? 128 : 64;
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sim_data.mem_latency = cfg1 & 0xf;
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sim_data.mem_page_miss = ((cfg1 >> 4) & 0xf) + ((cfg1 >> 31) & 0x1);
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}
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if (dev_priv->card_type == NV_04)
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nv04_calc_arb(&fifo_data, &sim_data);
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else
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nv10_calc_arb(&fifo_data, &sim_data);
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*burst = ilog2(fifo_data.burst >> 4);
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*lwm = fifo_data.lwm >> 3;
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}
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static void
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nv20_update_arb(int *burst, int *lwm)
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{
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unsigned int fifo_size, burst_size, graphics_lwm;
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fifo_size = 2048;
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burst_size = 512;
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graphics_lwm = fifo_size - burst_size;
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*burst = ilog2(burst_size >> 5);
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*lwm = graphics_lwm >> 3;
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}
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void
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nouveau_calc_arb(struct drm_device *dev, int vclk, int bpp, int *burst, int *lwm)
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{
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struct drm_nouveau_private *dev_priv = dev->dev_private;
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if (dev_priv->card_type < NV_20)
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nv04_update_arb(dev, vclk, bpp, burst, lwm);
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else if ((dev->pci_device & 0xfff0) == 0x0240 /*CHIPSET_C51*/ ||
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(dev->pci_device & 0xfff0) == 0x03d0 /*CHIPSET_C512*/) {
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*burst = 128;
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*lwm = 0x0480;
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} else
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nv20_update_arb(burst, lwm);
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}
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static int
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getMNP_single(struct drm_device *dev, struct pll_lims *pll_lim, int clk,
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struct nouveau_pll_vals *bestpv)
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{
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/* Find M, N and P for a single stage PLL
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*
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* Note that some bioses (NV3x) have lookup tables of precomputed MNP
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* values, but we're too lazy to use those atm
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*
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* "clk" parameter in kHz
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* returns calculated clock
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*/
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struct drm_nouveau_private *dev_priv = dev->dev_private;
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int cv = dev_priv->vbios.chip_version;
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int minvco = pll_lim->vco1.minfreq, maxvco = pll_lim->vco1.maxfreq;
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int minM = pll_lim->vco1.min_m, maxM = pll_lim->vco1.max_m;
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int minN = pll_lim->vco1.min_n, maxN = pll_lim->vco1.max_n;
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int minU = pll_lim->vco1.min_inputfreq;
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int maxU = pll_lim->vco1.max_inputfreq;
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int minP = pll_lim->max_p ? pll_lim->min_p : 0;
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int maxP = pll_lim->max_p ? pll_lim->max_p : pll_lim->max_usable_log2p;
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int crystal = pll_lim->refclk;
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int M, N, thisP, P;
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int clkP, calcclk;
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int delta, bestdelta = INT_MAX;
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int bestclk = 0;
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/* this division verified for nv20, nv18, nv28 (Haiku), and nv34 */
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/* possibly correlated with introduction of 27MHz crystal */
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if (dev_priv->card_type < NV_50) {
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if (cv < 0x17 || cv == 0x1a || cv == 0x20) {
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if (clk > 250000)
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maxM = 6;
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if (clk > 340000)
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maxM = 2;
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} else if (cv < 0x40) {
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if (clk > 150000)
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maxM = 6;
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if (clk > 200000)
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maxM = 4;
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if (clk > 340000)
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maxM = 2;
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}
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}
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P = pll_lim->max_p ? maxP : (1 << maxP);
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if ((clk * P) < minvco) {
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minvco = clk * maxP;
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maxvco = minvco * 2;
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}
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if (clk + clk/200 > maxvco) /* +0.5% */
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maxvco = clk + clk/200;
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/* NV34 goes maxlog2P->0, NV20 goes 0->maxlog2P */
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for (thisP = minP; thisP <= maxP; thisP++) {
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P = pll_lim->max_p ? thisP : (1 << thisP);
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clkP = clk * P;
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if (clkP < minvco)
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continue;
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if (clkP > maxvco)
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return bestclk;
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for (M = minM; M <= maxM; M++) {
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if (crystal/M < minU)
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return bestclk;
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if (crystal/M > maxU)
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continue;
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/* add crystal/2 to round better */
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N = (clkP * M + crystal/2) / crystal;
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if (N < minN)
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continue;
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if (N > maxN)
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break;
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/* more rounding additions */
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calcclk = ((N * crystal + P/2) / P + M/2) / M;
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delta = abs(calcclk - clk);
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/* we do an exhaustive search rather than terminating
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* on an optimality condition...
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*/
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if (delta < bestdelta) {
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bestdelta = delta;
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bestclk = calcclk;
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bestpv->N1 = N;
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bestpv->M1 = M;
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bestpv->log2P = thisP;
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if (delta == 0) /* except this one */
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return bestclk;
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}
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}
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}
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return bestclk;
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}
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static int
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getMNP_double(struct drm_device *dev, struct pll_lims *pll_lim, int clk,
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struct nouveau_pll_vals *bestpv)
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{
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/* Find M, N and P for a two stage PLL
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*
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* Note that some bioses (NV30+) have lookup tables of precomputed MNP
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* values, but we're too lazy to use those atm
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*
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* "clk" parameter in kHz
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* returns calculated clock
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*/
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struct drm_nouveau_private *dev_priv = dev->dev_private;
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int chip_version = dev_priv->vbios.chip_version;
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int minvco1 = pll_lim->vco1.minfreq, maxvco1 = pll_lim->vco1.maxfreq;
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int minvco2 = pll_lim->vco2.minfreq, maxvco2 = pll_lim->vco2.maxfreq;
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int minU1 = pll_lim->vco1.min_inputfreq, minU2 = pll_lim->vco2.min_inputfreq;
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int maxU1 = pll_lim->vco1.max_inputfreq, maxU2 = pll_lim->vco2.max_inputfreq;
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int minM1 = pll_lim->vco1.min_m, maxM1 = pll_lim->vco1.max_m;
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int minN1 = pll_lim->vco1.min_n, maxN1 = pll_lim->vco1.max_n;
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int minM2 = pll_lim->vco2.min_m, maxM2 = pll_lim->vco2.max_m;
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int minN2 = pll_lim->vco2.min_n, maxN2 = pll_lim->vco2.max_n;
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int maxlog2P = pll_lim->max_usable_log2p;
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int crystal = pll_lim->refclk;
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bool fixedgain2 = (minM2 == maxM2 && minN2 == maxN2);
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int M1, N1, M2, N2, log2P;
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int clkP, calcclk1, calcclk2, calcclkout;
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int delta, bestdelta = INT_MAX;
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int bestclk = 0;
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int vco2 = (maxvco2 - maxvco2/200) / 2;
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for (log2P = 0; clk && log2P < maxlog2P && clk <= (vco2 >> log2P); log2P++)
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;
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clkP = clk << log2P;
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if (maxvco2 < clk + clk/200) /* +0.5% */
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maxvco2 = clk + clk/200;
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for (M1 = minM1; M1 <= maxM1; M1++) {
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if (crystal/M1 < minU1)
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return bestclk;
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if (crystal/M1 > maxU1)
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continue;
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for (N1 = minN1; N1 <= maxN1; N1++) {
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calcclk1 = crystal * N1 / M1;
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if (calcclk1 < minvco1)
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continue;
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if (calcclk1 > maxvco1)
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break;
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for (M2 = minM2; M2 <= maxM2; M2++) {
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if (calcclk1/M2 < minU2)
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break;
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if (calcclk1/M2 > maxU2)
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continue;
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/* add calcclk1/2 to round better */
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N2 = (clkP * M2 + calcclk1/2) / calcclk1;
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if (N2 < minN2)
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continue;
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if (N2 > maxN2)
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break;
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if (!fixedgain2) {
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if (chip_version < 0x60)
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if (N2/M2 < 4 || N2/M2 > 10)
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continue;
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calcclk2 = calcclk1 * N2 / M2;
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if (calcclk2 < minvco2)
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break;
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if (calcclk2 > maxvco2)
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continue;
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} else
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calcclk2 = calcclk1;
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calcclkout = calcclk2 >> log2P;
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delta = abs(calcclkout - clk);
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/* we do an exhaustive search rather than terminating
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* on an optimality condition...
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*/
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if (delta < bestdelta) {
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bestdelta = delta;
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bestclk = calcclkout;
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bestpv->N1 = N1;
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bestpv->M1 = M1;
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bestpv->N2 = N2;
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bestpv->M2 = M2;
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bestpv->log2P = log2P;
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if (delta == 0) /* except this one */
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return bestclk;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
return bestclk;
|
|
}
|
|
|
|
int
|
|
nouveau_calc_pll_mnp(struct drm_device *dev, struct pll_lims *pll_lim, int clk,
|
|
struct nouveau_pll_vals *pv)
|
|
{
|
|
int outclk;
|
|
|
|
if (!pll_lim->vco2.maxfreq)
|
|
outclk = getMNP_single(dev, pll_lim, clk, pv);
|
|
else
|
|
outclk = getMNP_double(dev, pll_lim, clk, pv);
|
|
|
|
if (!outclk)
|
|
NV_ERROR(dev, "Could not find a compatible set of PLL values\n");
|
|
|
|
return outclk;
|
|
}
|