rockbox/utils/regtools/qeditor/std_analysers.cpp
Amaury Pouly 2a3a6bb4b3 regtools/qeditor: compute RAM size
Change-Id: I7bfb5cc25bc3dc55f379b2319b20dc9510434de0
2017-02-04 17:19:20 +01:00

1395 lines
49 KiB
C++

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2014 by Amaury Pouly
*
* 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; either version 2
* of the License, or (at your option) any later version.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include "std_analysers.h"
#include <QDebug>
/**
* AnalyserEx
*/
AnalyserEx::AnalyserEx(const soc_desc::soc_ref_t& soc, IoBackend *backend)
:Analyser(soc, backend), m_helper(backend, soc)
{
}
bool AnalyserEx::ReadRegister(const QString& path, soc_word_t& val)
{
return m_helper.ReadRegister(m_helper.ParsePath(path), val);
}
bool AnalyserEx::ReadRegisterOld(const QString& dev, const QString& reg, soc_word_t& val)
{
return ReadRegister(dev + "." + reg, val);
}
bool AnalyserEx::ReadField(const QString& path, const QString& field, soc_word_t& val)
{
return m_helper.ReadRegisterField(m_helper.ParsePath(path), field, val);
}
bool AnalyserEx::ReadFieldOld(const QString& dev, const QString& reg,
const QString& field, soc_word_t& val)
{
return ReadField(dev + "." + reg, field, val);
}
/**
* Clock analyser
*/
ClockAnalyser::ClockAnalyser(const soc_desc::soc_ref_t& soc, IoBackend *backend)
:AnalyserEx(soc, backend)
{
m_group = new QGroupBox("Clock Analyser");
QVBoxLayout *layout = new QVBoxLayout;
m_group->setLayout(layout);
m_tree_widget = new QTreeWidget;
layout->addWidget(m_tree_widget);
m_tree_widget->setColumnCount(2);
QStringList list;
list << "Name" << "Frequency";
m_tree_widget->setHeaderLabels(list);
FillTree();
}
ClockAnalyser::~ClockAnalyser()
{
delete m_group;
}
QWidget *ClockAnalyser::GetWidget()
{
return m_group;
}
bool ClockAnalyser::SupportSoc(const QString& soc_name)
{
return soc_name == "imx233"
|| soc_name == "rk27xx"
|| soc_name == "atj213x"
|| soc_name == "jz4760b"
|| soc_name == "stmp3700";
}
QString ClockAnalyser::GetFreq(unsigned freq)
{
if(freq >= 1000000)
{
if((freq % 1000000) == 0)
return QString().sprintf("%d MHz", freq / 1000000);
else
return QString().sprintf("%.3f MHz", freq / 1000000.0);
}
if(freq >= 1000)
{
if((freq % 1000) == 0)
return QString().sprintf("%d KHz", freq / 1000);
else
return QString().sprintf("%.3f KHz", freq / 1000.0);
}
return QString().sprintf("%d Hz", freq);
}
QTreeWidgetItem *ClockAnalyser::AddClock(QTreeWidgetItem *parent, const QString& name,
int freq, int mul, int div)
{
if(freq == FROM_PARENT)
{
int64_t f = GetClockFreq(parent);
f *= mul;
f /= div;
freq = f;
}
QTreeWidgetItem *item = new QTreeWidgetItem(parent, QStringList() << name
<< (freq == INVALID ? "<invalid>" : freq == 0 ? "<disabled>" : GetFreq(freq)));
item->setData(1, Qt::UserRole, freq);
if(freq == DISABLED || freq == INVALID || (parent && parent->isDisabled()))
item->setDisabled(true);
if(!parent)
m_tree_widget->addTopLevelItem(item);
return item;
}
int ClockAnalyser::GetClockFreq(QTreeWidgetItem *item)
{
return item->data(1, Qt::UserRole).toInt();
}
void ClockAnalyser::FillTree()
{
m_tree_widget->clear();
if(m_soc.get()->name == "imx233") FillTreeIMX233();
if(m_soc.get()->name == "stmp3700") FillTreeIMX233();
else if(m_soc.get()->name == "rk27xx") FillTreeRK27XX();
else if(m_soc.get()->name == "atj213x") FillTreeATJ213X();
else if(m_soc.get()->name == "jz4760b") FillTreeJZ4760B();
m_tree_widget->expandAll();
m_tree_widget->resizeColumnToContents(0);
}
void ClockAnalyser::FillTreeJZ4760B()
{
AddClock(0, "RTCLK", 32768);
// assume EXCLK is 12MHz, we have no way to knowing for sure but this is the
// recommended value anyway
QTreeWidgetItem *exclk = AddClock(0, "EXCLK", 12000000);
// PLL0
soc_word_t pllm, plln, pllod, pllbypass;
QTreeWidgetItem *pll0 = 0;
if(ReadFieldOld("CPM", "PLLCTRL0", "FEED_DIV", pllm) &&
ReadFieldOld("CPM", "PLLCTRL0", "IN_DIV", plln) &&
ReadFieldOld("CPM", "PLLCTRL0", "OUT_DIV", pllod) &&
ReadFieldOld("CPM", "PLLCTRL0", "BYPASS", pllbypass))
{
pll0 = AddClock(exclk, "PLL0", FROM_PARENT, pllbypass ? 1 : 2 * pllm,
pllbypass ? 1 : plln * (1 << pllod));
}
else
pll0 = AddClock(exclk, "PLL0", INVALID);
// PLL1
soc_word_t plldiv, src_sel;
QTreeWidgetItem *pll1 = 0;
if(ReadFieldOld("CPM", "PLLCTRL1", "FEED_DIV", pllm) &&
ReadFieldOld("CPM", "PLLCTRL1", "IN_DIV", plln) &&
ReadFieldOld("CPM", "PLLCTRL1", "OUT_DIV", pllod) &&
ReadFieldOld("CPM", "PLLCTRL1", "SRC_SEL", src_sel) &&
ReadFieldOld("CPM", "PLLCTRL1", "PLL0_DIV", plldiv))
{
pll1 = AddClock(src_sel ? pll0 : exclk, "PLL1", FROM_PARENT, 2 * pllm,
plln * (1 << pllod) * (src_sel ? plldiv : 1));
}
else
pll1 = AddClock(exclk, "PLL1", INVALID);
// system clocks
const int NR_SYSCLK = 6;
const char *sysclk[NR_SYSCLK] = { "CCLK", "SCLK", "PCLK", "HCLK", "H2CLK", "MCLK"};
for(int i = 0; i < NR_SYSCLK; i++)
{
soc_word_t div = 0;
std::string field = std::string(sysclk[i]) + "_DIV";
if(ReadFieldOld("CPM", "SYSCLK", field.c_str(), div))
{
switch(div)
{
case 0: div = 1; break;
case 1: div = 2; break;
case 2: div = 3; break;
case 3: div = 4; break;
case 4: div = 6; break;
case 5: div = 8; break;
default: div = 0; break;
}
}
if(div != 0)
AddClock(pll0, sysclk[i], FROM_PARENT, 1, div);
else
AddClock(pll0, sysclk[i], INVALID);
}
// common to msc, i2s, lcd, uhc, otg, ssi, pcm, gpu, gps
soc_word_t pll_div;
if(ReadFieldOld("CPM", "SYSCLK", "PLL_DIV", pll_div))
pll_div = pll_div ? 1 : 2;
else
pll_div = 1; // error
// lcd
soc_word_t pll_sel, div;
if(ReadFieldOld("CPM", "LCDCLK", "DIV", div) &&
ReadFieldOld("CPM", "LCDCLK", "PLL_SEL", pll_sel))
{
AddClock(pll_sel ? pll1 : pll0, "LCDCLK",
FROM_PARENT, 1, pll_div * (div + 1));
}
else
AddClock(exclk, "LCDCLK", INVALID);
}
void ClockAnalyser::FillTreeATJ213X()
{
soc_word_t pllbypass, pllclk, en, coreclks, tmp0, tmp1, tmp2, tmp3;
// system oscillators 32.768k and 24M
QTreeWidgetItem *losc_clk = AddClock(0, "losc clk", 32768);
QTreeWidgetItem *hosc_clk = AddClock(0, "hosc clk", 24000000);
// core pll
QTreeWidgetItem *corepll = 0;
if(ReadFieldOld("CMU", "COREPLL", "CPEN", en) &&
ReadFieldOld("CMU", "COREPLL", "CPBY", pllbypass) &&
ReadFieldOld("CMU", "COREPLL", "CPCK", pllclk))
{
corepll = AddClock(hosc_clk, "core pll", en ? FROM_PARENT : DISABLED,
pllbypass ? 1 : pllclk, pllbypass ? 1 : 4);
}
else
{
corepll = AddClock(hosc_clk, "core pll", INVALID);
}
// dsp pll
QTreeWidgetItem *dsppll = 0;
if(ReadFieldOld("CMU", "DSPPLL", "DPEN", en) &&
ReadFieldOld("CMU", "DSPPLL", "DPCK", pllclk))
{
dsppll = AddClock(hosc_clk, "dsp pll", en ? FROM_PARENT : DISABLED,
pllbypass ? 1 : pllclk, pllbypass ? 1 : 4);
}
else
{
dsppll = AddClock(hosc_clk, "dsp pll", INVALID);
}
// audio pll
QTreeWidgetItem *adcpll = 0;
QTreeWidgetItem *dacpll = 0;
if(ReadFieldOld("CMU", "AUDIOPLL", "APEN", en) &&
ReadFieldOld("CMU", "AUDIOPLL", "ADCCLK", tmp0) &&
ReadFieldOld("CMU", "AUDIOPLL", "DACCLK", tmp1))
{
if(en)
{
adcpll = AddClock(hosc_clk, "audio adc pll", tmp0 ? 22579200 : 24576000);
dacpll = AddClock(hosc_clk, "audio dac pll", tmp1 ? 22579200 : 24576000);
}
else
{
adcpll = AddClock(hosc_clk, "audio adc pll", DISABLED);
dacpll = AddClock(hosc_clk, "audio dac pll", DISABLED);
}
}
else
{
adcpll = AddClock(hosc_clk, "audio adc pll", INVALID);
dacpll = AddClock(hosc_clk, "audio dac pll", INVALID);
}
// audio clocks
QTreeWidgetItem *adcclk = 0;
QTreeWidgetItem *dacclk = 0;
if(ReadFieldOld("CMU", "AUDIOPLL", "ADCCLK", tmp0) &&
ReadFieldOld("CMU", "AUDIOPLL", "DACCLK", tmp1))
{
adcclk = AddClock(adcpll, "audio adc clk", FROM_PARENT, 1, tmp0+1);
dacclk = AddClock(dacpll, "audio dac clk", FROM_PARENT, 1, tmp1+1);
}
else
{
adcclk = AddClock(adcpll, "audio adc clk", INVALID);
dacclk = AddClock(adcpll, "audio dac clk", INVALID);
}
// cpu clock
QTreeWidgetItem *cpuclk = 0;
if(ReadFieldOld("CMU", "BUSCLK", "CORECLKS", coreclks) &&
ReadFieldOld("CMU", "BUSCLK", "CCLKDIV", tmp0))
{
if(coreclks == 0)
cpuclk = AddClock(losc_clk, "cpu clk", FROM_PARENT, 1, tmp0+1);
else if(coreclks == 1)
cpuclk = AddClock(hosc_clk, "cpu clk", FROM_PARENT, 1, tmp0+1);
else if(coreclks == 2)
cpuclk = AddClock(corepll, "cpu clk", FROM_PARENT, 1, tmp0+1);
else
cpuclk = AddClock(corepll, "cpu clk", INVALID);
}
else
{
cpuclk = AddClock(corepll, "cpu clk", INVALID);
}
// system clock
QTreeWidgetItem *sysclk = 0;
if(ReadFieldOld("CMU", "BUSCLK", "SCLKDIV", tmp0))
sysclk = AddClock(cpuclk, "system clk", FROM_PARENT, 1, tmp0+1);
else
sysclk = AddClock(cpuclk, "system clk", INVALID);
// peripherial clk
QTreeWidgetItem *pclk = 0;
if(ReadFieldOld("CMU", "BUSCLK", "PCLKDIV", tmp0))
pclk = AddClock(sysclk, "peripherial clk", FROM_PARENT, 1, tmp0 ? tmp0+1 : 2);
else
pclk = AddClock(sysclk, "peripherial clk", INVALID);
// sdram clk
QTreeWidgetItem *sdrclk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "SDRC", en) &&
ReadFieldOld("CMU", "DEVCLKEN", "SDRM", tmp0) &&
ReadFieldOld("SDR", "EN", "EN", tmp1) &&
ReadFieldOld("CMU", "SDRCLK", "SDRDIV", tmp2))
{
en &= tmp0 & tmp1;
sdrclk = AddClock(sysclk, "sdram clk", en ? FROM_PARENT: DISABLED, 1, tmp2+1);
}
else
sdrclk = AddClock(sysclk, "sdram clk", INVALID);
// nand clk
QTreeWidgetItem *nandclk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "NAND", en) &&
ReadFieldOld("CMU", "NANDCLK", "NANDDIV", tmp0))
nandclk = AddClock(corepll, "nand clk", en ? FROM_PARENT : DISABLED, 1, tmp0+1);
else
nandclk = AddClock(corepll, "nand clk", INVALID);
// sd clk
QTreeWidgetItem *sdclk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "SD", tmp0) &&
ReadFieldOld("CMU", "SDCLK", "CKEN" , tmp1) &&
ReadFieldOld("CMU", "SDCLK", "D128" , tmp2) &&
ReadFieldOld("CMU", "SDCLK", "SDDIV" , tmp3))
{
en = tmp0 & tmp1;
sdclk = AddClock(corepll, "sd clk", en ? FROM_PARENT : DISABLED,
1, tmp2 ? 128*(tmp3+1) : (tmp3));
}
else
sdclk = AddClock(corepll, "sd clk", INVALID);
// mha clk
QTreeWidgetItem *mhaclk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "MHA", en) &&
ReadFieldOld("CMU", "MHACLK", "MHADIV", tmp1))
mhaclk = AddClock(corepll, "mha clk", en ? FROM_PARENT : DISABLED,
1, tmp1+1);
else
mhaclk = AddClock(corepll, "mha clk", INVALID);
// mca clk
QTreeWidgetItem *mcaclk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "MCA", en) &&
ReadFieldOld("CMU", "MCACLK", "MCADIV", tmp1))
mcaclk = AddClock(corepll, "mca clk", en ? FROM_PARENT : DISABLED,
1, tmp1+1);
else
mcaclk = AddClock(corepll, "mca clk", INVALID);
// backlight pwm
QTreeWidgetItem *pwmclk = 0;
if(ReadFieldOld("CMU", "FMCLK", "BCKE", en) &&
ReadFieldOld("CMU", "FMCLK", "BCKS", tmp1) &&
ReadFieldOld("CMU", "FMCLK", "BCKCON", tmp2))
{
if(tmp1)
{
// HOSC/8 input clk
pwmclk = AddClock(hosc_clk, "pwm clk", en ? FROM_PARENT : DISABLED,
1, 3*(tmp2+1));
}
else
{
// LOSC input clk
pwmclk = AddClock(losc_clk, "pwm clk", en ? FROM_PARENT : DISABLED,
1, tmp2+1);
}
}
else
pwmclk = AddClock(losc_clk, "pwm clk", INVALID);
// i2c clk
QTreeWidgetItem *i2c1clk = 0;
QTreeWidgetItem *i2c2clk = 0;
if(ReadFieldOld("CMU", "DEVCLKEN", "I2C", en) &&
ReadFieldOld("I2C1", "CTL", "EN", tmp0) &&
ReadFieldOld("I2C1", "CLKDIV", "CLKDIV", tmp1))
{
en &= tmp0;
i2c1clk = AddClock(pclk, "i2c1 clk", en ? FROM_PARENT : DISABLED,
1, 16*(tmp1+1));
}
else
{
i2c1clk = AddClock(pclk, "i2c1 clk", INVALID);
}
if(ReadFieldOld("CMU", "DEVCLKEN", "I2C", en) &&
ReadFieldOld("I2C2", "CTL", "EN", tmp0) &&
ReadFieldOld("I2C2", "CLKDIV", "CLKDIV", tmp1))
{
en &= tmp0;
i2c2clk = AddClock(pclk, "i2c2 clk", en ? FROM_PARENT : DISABLED,
1, 16*(tmp1+1));
}
else
{
i2c2clk = AddClock(pclk, "i2c2 clk", INVALID);
}
Q_UNUSED(dsppll);
Q_UNUSED(adcclk);
Q_UNUSED(dacclk);
Q_UNUSED(sdrclk);
Q_UNUSED(nandclk);
Q_UNUSED(sdclk);
Q_UNUSED(mhaclk);
Q_UNUSED(mcaclk);
Q_UNUSED(pwmclk);
Q_UNUSED(i2c1clk);
Q_UNUSED(i2c2clk);
}
void ClockAnalyser::FillTreeRK27XX()
{
soc_word_t value, value2, value3, value4;
soc_word_t bypass, clkr, clkf, clkod, pll_off;
QTreeWidgetItem *xtal_clk = AddClock(0, "xtal clk", 24000000);
// F = (Fref*F)/R/OD = (Fref*F)/R/OD
QTreeWidgetItem *arm_pll = 0;
if(ReadFieldOld("SCU", "PLLCON1", "ARM_PLL_BYPASS", bypass) &&
ReadFieldOld("SCU", "PLLCON1", "ARM_PLL_CLKR", clkr) &&
ReadFieldOld("SCU", "PLLCON1", "ARM_PLL_CLKF", clkf) &&
ReadFieldOld("SCU", "PLLCON1", "ARM_PLL_CLKOD", clkod) &&
ReadFieldOld("SCU", "PLLCON1", "ARM_PLL_POWERDOWN", pll_off))
{
arm_pll = AddClock(xtal_clk, "arm pll", pll_off ? DISABLED : FROM_PARENT,
bypass ? 1 : clkf+1, bypass ? 1 : (clkr+1)*(clkod+1));
}
else
{
arm_pll = AddClock(xtal_clk, "arm pll", INVALID);
}
QTreeWidgetItem *arm_clk = 0;
QTreeWidgetItem *hclk = 0;
QTreeWidgetItem *pclk = 0;
if(ReadFieldOld("SCU", "DIVCON1", "ARM_SLOW_MODE", value) &&
ReadFieldOld("SCU", "DIVCON1", "ARM_CLK_DIV", value2) &&
ReadFieldOld("SCU", "DIVCON1", "PCLK_CLK_DIV", value3))
{
arm_clk = AddClock(value ? xtal_clk : arm_pll, "arm clk", FROM_PARENT, 1, value2 ? 2 : 1);
hclk = AddClock(arm_clk, "hclk", FROM_PARENT, 1, value2 ? 1 : 2);
pclk = AddClock(hclk, "pclk", FROM_PARENT, 1, (1<<value3));
}
else
{
arm_clk = AddClock(xtal_clk, "arm_clk", INVALID);
hclk = AddClock(xtal_clk, "hclk", INVALID);
pclk = AddClock(xtal_clk, "pclk", INVALID);
}
QTreeWidgetItem *dsp_pll = 0;
if(ReadFieldOld("SCU", "PLLCON2", "DSP_PLL_BYPASS", bypass) &&
ReadFieldOld("SCU", "PLLCON2", "DSP_PLL_CLKR", clkr) &&
ReadFieldOld("SCU", "PLLCON2", "DSP_PLL_CLKF", clkf) &&
ReadFieldOld("SCU", "PLLCON2", "DSP_PLL_CLKOD", clkod) &&
ReadFieldOld("SCU", "PLLCON2", "DSP_PLL_POWERDOWN", pll_off))
{
dsp_pll = AddClock(xtal_clk, "dsp pll", pll_off ? DISABLED : FROM_PARENT,
bypass ? 1 : clkf+1, bypass ? 1 : (clkr+1)*(clkod+1));
}
else
{
dsp_pll = AddClock(xtal_clk, "dsp_pll", INVALID);
}
QTreeWidgetItem *dsp_clk = AddClock(dsp_pll, "dsp clk", FROM_PARENT);
QTreeWidgetItem *codec_pll = 0;
if(ReadFieldOld("SCU", "PLLCON3", "CODEC_PLL_BYPASS", bypass) &&
ReadFieldOld("SCU", "PLLCON3", "CODEC_PLL_CLKR", clkr) &&
ReadFieldOld("SCU", "PLLCON3", "CODEC_PLL_CLKF", clkf) &&
ReadFieldOld("SCU", "PLLCON3", "CODEC_PLL_CLKOD", clkod) &&
ReadFieldOld("SCU", "PLLCON3", "CODEC_PLL_POWERDOWN", pll_off))
{
codec_pll = AddClock(xtal_clk, "codec pll", pll_off ? DISABLED : FROM_PARENT,
bypass ? 1 : clkf+1, bypass ? 1 : (clkr+1)*(clkod+1));
}
else
{
codec_pll = AddClock(xtal_clk, "codec_pll", INVALID);
}
QTreeWidgetItem *codec_clk = 0;
if(ReadFieldOld("SCU", "DIVCON1", "CODEC_CLK_SRC", value) &&
ReadFieldOld("SCU", "DIVCON1", "CODEC_CLK_DIV", value2))
{
codec_clk = AddClock(value ? xtal_clk : codec_pll, "codec clk", FROM_PARENT, 1, value ? 1 : (value2 + 1));
}
else
{
codec_clk = AddClock(xtal_clk, "codec_clk", INVALID);
}
QTreeWidgetItem *lsadc_clk = 0;
if(ReadFieldOld("SCU", "DIVCON1", "LSADC_CLK_DIV", value))
{
lsadc_clk = AddClock(pclk, "lsadc clk", FROM_PARENT, 1, (value+1));
}
else
{
lsadc_clk = AddClock(xtal_clk, "lsadc clk", INVALID);
}
QTreeWidgetItem *lcdc_clk = 0;
if(ReadFieldOld("SCU", "DIVCON1", "LCDC_CLK", value) &&
ReadFieldOld("SCU", "DIVCON1", "LCDC_CLK_DIV", value2) &&
ReadFieldOld("SCU", "DIVCON1", "LCDC_CLK_DIV_SRC", value3))
{
if(value)
{
lcdc_clk = AddClock(xtal_clk, "lcdc clk", FROM_PARENT);
}
else
{
if(value3 == 0)
lcdc_clk = AddClock(arm_pll, "lcdc clk", FROM_PARENT, 1, value2+1);
else if(value3 == 1)
lcdc_clk = AddClock(dsp_pll, "lcdc clk", FROM_PARENT, 1, value2+1);
else
lcdc_clk = AddClock(codec_pll, "lcdc clk", FROM_PARENT, 1, value2+1);
}
}
else
{
lcdc_clk = AddClock(xtal_clk, "lcdc clk", INVALID);
}
QTreeWidgetItem *pwm0_clk = 0;
if(ReadFieldOld("PWM0", "LRC", "TR", value) &&
ReadFieldOld("PWM0", "CTRL", "PRESCALE", value3) &&
ReadFieldOld("PWM0", "CTRL", "PWM_EN", value4))
{
pwm0_clk = AddClock(pclk, "pwm0 clk", value4 ? FROM_PARENT : DISABLED, 1, 2*value*(1<<value3));
}
else
{
pwm0_clk = AddClock(xtal_clk, "pwm0 clk", INVALID);
}
QTreeWidgetItem *pwm1_clk = 0;
if(ReadFieldOld("PWM1", "LRC", "TR", value) &&
ReadFieldOld("PWM1", "CTRL", "PRESCALE", value3) &&
ReadFieldOld("PWM1", "CTRL", "PWM_EN", value4))
{
pwm1_clk = AddClock(pclk, "pwm1 clk", value4 ? FROM_PARENT : DISABLED, 1, 2*value*(1<<value3));
}
else
{
pwm1_clk = AddClock(xtal_clk, "pwm1 clk", INVALID);
}
QTreeWidgetItem *pwm2_clk = 0;
if(ReadFieldOld("PWM2", "LRC", "TR", value) &&
ReadFieldOld("PWM2", "CTRL", "PRESCALE", value3) &&
ReadFieldOld("PWM2", "CTRL", "PWM_EN", value4))
{
pwm2_clk = AddClock(pclk, "pwm2 clk", value4 ? FROM_PARENT : DISABLED, 1, 2*value*(1<<value3));
}
else
{
pwm2_clk = AddClock(xtal_clk, "pwm2 clk", INVALID);
}
QTreeWidgetItem *pwm3_clk = 0;
if(ReadFieldOld("PWM3", "LRC", "TR", value) &&
ReadFieldOld("PWM3", "CTRL", "PRESCALE", value3) &&
ReadFieldOld("PWM3", "CTRL", "PWM_EN", value4))
{
pwm3_clk = AddClock(pclk, "pwm3", value4 ? FROM_PARENT : DISABLED, 1, 2*value*(1<<value3));
}
else
{
pwm3_clk = AddClock(xtal_clk, "pwm3 clk", INVALID);
}
QTreeWidgetItem *sdmmc_clk = 0;
if(ReadFieldOld("SD", "CTRL", "DIVIDER", value))
{
sdmmc_clk = AddClock(pclk, "sd clk", FROM_PARENT, 1, value+1);
}
else
{
sdmmc_clk = AddClock(xtal_clk, "sd clk", INVALID);
}
Q_UNUSED(dsp_clk);
Q_UNUSED(codec_clk);
Q_UNUSED(lsadc_clk);
Q_UNUSED(lcdc_clk);
Q_UNUSED(pwm0_clk);
Q_UNUSED(pwm1_clk);
Q_UNUSED(pwm2_clk);
Q_UNUSED(pwm3_clk);
Q_UNUSED(sdmmc_clk);
}
void ClockAnalyser::FillTreeIMX233()
{
/* work for stmp3700 and imx233 */
soc_word_t value, value2, value3;
QTreeWidgetItem *ring_osc = 0;
if(ReadFieldOld("POWER", "MINPWR", "ENABLE_OSC", value))
ring_osc = AddClock(0, "ring_clk24m", value ? 24000000 : DISABLED);
else
ring_osc = AddClock(0, "ring_clk24m", INVALID);
QTreeWidgetItem *xtal_osc = 0;
if(ReadFieldOld("POWER", "MINPWR", "PWD_XTAL24", value))
xtal_osc = AddClock(0, "xtal_clk24m", value ? DISABLED : 24000000);
else
xtal_osc = AddClock(0, "xtal_clk24m", INVALID);
QTreeWidgetItem *ref_xtal = 0;
if(ReadFieldOld("POWER", "MINPWR", "SELECT_OSC", value))
ref_xtal = AddClock(value ? ring_osc : xtal_osc, "ref_xtal", FROM_PARENT);
else
ref_xtal = AddClock(0, "ref_xtal", INVALID);
QTreeWidgetItem *ref_pll = 0;
if(ReadFieldOld("CLKCTRL", "PLLCTRL0", "POWER", value))
ref_pll = AddClock(ref_xtal, "ref_pll", FROM_PARENT, 20);
else
ref_pll = AddClock(0, "ref_pll", INVALID);
QTreeWidgetItem *ref_io = 0;
if(ReadFieldOld("CLKCTRL", "FRAC", "CLKGATEIO", value) &&
ReadFieldOld("CLKCTRL", "FRAC", "IOFRAC", value2))
ref_io = AddClock(ref_pll, "ref_io", value ? DISABLED : FROM_PARENT, 18, value2);
else
ref_io = AddClock(ref_pll, "ref_io", INVALID);
QTreeWidgetItem *ref_pix = 0;
if(ReadFieldOld("CLKCTRL", "FRAC", "CLKGATEPIX", value) &&
ReadFieldOld("CLKCTRL", "FRAC", "PIXFRAC", value2))
ref_pix = AddClock(ref_pll, "ref_pix", value ? DISABLED : FROM_PARENT, 18, value2);
else
ref_pix = AddClock(ref_pll, "ref_pix", INVALID);
QTreeWidgetItem *ref_emi = 0;
if(ReadFieldOld("CLKCTRL", "FRAC", "CLKGATEEMI", value) &&
ReadFieldOld("CLKCTRL", "FRAC", "EMIFRAC", value2))
ref_emi = AddClock(ref_pll, "ref_emi", value ? DISABLED : FROM_PARENT, 18, value2);
else
ref_emi = AddClock(ref_pll, "ref_emi", INVALID);
QTreeWidgetItem *ref_cpu = 0;
if(ReadFieldOld("CLKCTRL", "FRAC", "CLKGATECPU", value) &&
ReadFieldOld("CLKCTRL", "FRAC", "CPUFRAC", value2))
ref_cpu = AddClock(ref_pll, "ref_cpu", value ? DISABLED : FROM_PARENT, 18, value2);
else
ref_cpu = AddClock(ref_pll, "ref_cpu", INVALID);
QTreeWidgetItem *clk_p = 0;
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_CPU", value))
{
if(!value)
{
if(ReadFieldOld("CLKCTRL", "CPU", "DIV_CPU", value2))
clk_p = AddClock(ref_cpu, "clk_p", FROM_PARENT, 1, value2);
else
clk_p = AddClock(ref_cpu, "clk_p", INVALID);
}
else
{
if(ReadFieldOld("CLKCTRL", "CPU", "DIV_XTAL_FRAC_EN", value) &&
ReadFieldOld("CLKCTRL", "CPU", "DIV_XTAL", value2))
clk_p = AddClock(ref_xtal, "clk_p", FROM_PARENT, value ? 1024 : 1, value2);
else
clk_p = AddClock(ref_xtal, "clk_p", INVALID);
}
}
else
clk_p = AddClock(ref_xtal, "clk_p", INVALID);
QTreeWidgetItem *clk_h = 0;
if(ReadFieldOld("CLKCTRL", "HBUS", "DIV_FRAC_EN", value) &&
ReadFieldOld("CLKCTRL", "HBUS", "DIV", value2))
clk_h = AddClock(clk_p, "clk_h", FROM_PARENT, value ? 32 : 1, value2);
else
clk_h = AddClock(clk_p, "clk_h", INVALID);
QTreeWidgetItem *clk_x = 0;
if(ReadFieldOld("CLKCTRL", "XBUS", "DIV", value))
clk_x = AddClock(ref_xtal, "clk_x", FROM_PARENT, 1, value);
else
clk_x = AddClock(ref_xtal, "clk_x", INVALID);
if(ReadFieldOld("CLKCTRL", "XTAL", "UART_CLK_GATE", value))
AddClock(ref_xtal, "clk_uart", value ? DISABLED : FROM_PARENT);
else
AddClock(ref_xtal, "clk_uart", INVALID);
if(ReadFieldOld("CLKCTRL", "XTAL", "FILT_CLK24M_GATE", value))
AddClock(ref_xtal, "clk_filt24m", value ? DISABLED : FROM_PARENT);
else
AddClock(ref_xtal, "clk_filt24m", INVALID);
if(ReadFieldOld("CLKCTRL", "XTAL", "PWM_CLK24M_GATE", value))
AddClock(ref_xtal, "clk_pwm24m", value ? DISABLED : FROM_PARENT);
else
AddClock(ref_xtal, "clk_pwm24m", INVALID);
if(ReadFieldOld("CLKCTRL", "XTAL", "DRI_CLK24M_GATE", value))
AddClock(ref_xtal, "clk_dri24m", value ? DISABLED : FROM_PARENT);
else
AddClock(ref_xtal, "clk_dri24m", INVALID);
if(ReadFieldOld("CLKCTRL", "XTAL", "DIGCTRL_CLK1M_GATE", value))
AddClock(ref_xtal, "clk_1m", value ? DISABLED : FROM_PARENT, 1, 24);
else
AddClock(ref_xtal, "clk_1m", INVALID);
QTreeWidgetItem *clk_32k = 0;
if(ReadFieldOld("CLKCTRL", "XTAL", "TIMROT_CLK32K_GATE", value))
clk_32k = AddClock(ref_xtal, "clk_32k", value ? DISABLED : FROM_PARENT, 1, 750);
else
clk_32k = AddClock(ref_xtal, "clk_32k", INVALID);
AddClock(clk_32k, "clk_adc", FROM_PARENT, 1, 16);
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_PIX", value) &&
ReadFieldOld("CLKCTRL", "PIX", "DIV", value2))
AddClock(value ? ref_xtal : ref_pix, "clk_pix", FROM_PARENT, 1, value2);
else
AddClock(ref_xtal, "clk_p", INVALID);
QTreeWidgetItem *clk_ssp = 0;
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_SSP", value) &&
ReadFieldOld("CLKCTRL", "SSP", "DIV", value2) &&
ReadFieldOld("CLKCTRL", "SSP", "CLKGATE", value3))
clk_ssp = AddClock(value ? ref_xtal : ref_io, "clk_ssp", value3 ? DISABLED : FROM_PARENT, 1, value2);
else
clk_ssp = AddClock(ref_xtal, "clk_ssp", INVALID);
if(ReadFieldOld("SSP[1]", "TIMING", "CLOCK_DIVIDE", value) &&
ReadFieldOld("SSP[1]", "TIMING", "CLOCK_RATE", value2) &&
ReadFieldOld("SSP[1]", "CTRL0", "CLKGATE", value3))
AddClock(clk_ssp, "clk_ssp1", value3 ? DISABLED : FROM_PARENT, 1, value * (1 + value2));
else
AddClock(clk_ssp, "clk_ssp1", INVALID);
if(ReadFieldOld("SSP[2]", "TIMING", "CLOCK_DIVIDE", value) &&
ReadFieldOld("SSP[2]", "TIMING", "CLOCK_RATE", value2) &&
ReadFieldOld("SSP[2]", "CTRL0", "CLKGATE", value3))
AddClock(clk_ssp, "clk_ssp2", value3 ? DISABLED : FROM_PARENT, 1, value * (1 + value2));
else
AddClock(clk_ssp, "clk_ssp2", INVALID);
QTreeWidgetItem *clk_gpmi = 0;
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_GPMI", value) &&
ReadFieldOld("CLKCTRL", "GPMI", "DIV", value2) &&
ReadFieldOld("CLKCTRL", "GPMI", "CLKGATE", value3))
clk_gpmi = AddClock(value ? ref_xtal : ref_io, "clk_gpmi", value3 ? DISABLED : FROM_PARENT, 1, value2);
else
clk_gpmi = AddClock(ref_xtal, "clk_p", INVALID);
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_EMI", value))
{
if(!value)
{
if(ReadFieldOld("CLKCTRL", "EMI", "DIV_EMI", value2) &&
ReadFieldOld("CLKCTRL", "EMI", "CLKGATE", value3))
AddClock(ref_emi, "clk_emi", value3 ? DISABLED : FROM_PARENT, 1, value2);
else
AddClock(ref_emi, "clk_emi", INVALID);
}
else
{
if(ReadFieldOld("CLKCTRL", "EMI", "DIV_XTAL", value2) &&
ReadFieldOld("CLKCTRL", "EMI", "CLKGATE", value3))
AddClock(ref_xtal, "clk_emi", value3 ? DISABLED : FROM_PARENT, 1, value2);
else
AddClock(ref_xtal, "clk_emi", INVALID);
}
}
else
clk_p = AddClock(ref_xtal, "clk_emi", INVALID);
QTreeWidgetItem *ref_vid = AddClock(ref_pll, "clk_vid", FROM_PARENT);
if(ReadFieldOld("CLKCTRL", "TV", "CLK_TV108M_GATE", value) &&
ReadFieldOld("CLKCTRL", "TV", "CLK_TV_GATE", value2))
{
QTreeWidgetItem *clk_tv108m = AddClock(ref_vid, "clk_tv108m", value ? DISABLED : FROM_PARENT, 1, 4);
AddClock(clk_tv108m, "clk_tv54m", value2 ? DISABLED : FROM_PARENT, 1, 2);
AddClock(clk_tv108m, "clk_tv27m", value2 ? DISABLED : FROM_PARENT, 1, 4);
}
if(ReadFieldOld("CLKCTRL", "PLLCTRL0", "EN_USB_CLKS", value))
AddClock(ref_pll, "utmi_clk480m", value ? FROM_PARENT : DISABLED);
else
AddClock(ref_pll, "utmi_clk480m", INVALID);
QTreeWidgetItem *xtal_clk32k = 0;
if(ReadFieldOld("RTC", "PERSISTENT0", "XTAL32_FREQ", value) &&
ReadFieldOld("RTC", "PERSISTENT0", "XTAL32KHZ_PWRUP", value2))
xtal_clk32k = AddClock(0, "xtal_clk32k", value2 == 0 ? DISABLED : value ? 32000 : 32768);
else
xtal_clk32k = AddClock(0, "xtal_clk32k", INVALID);
if(ReadFieldOld("RTC", "PERSISTENT0", "CLOCKSOURCE", value))
AddClock(value ? xtal_clk32k : ref_xtal, "clk_rtc32k", FROM_PARENT, 1, value ? 1 : 768);
else
AddClock(ref_xtal, "clk_rtc32k", INVALID);
Q_UNUSED(clk_x);
Q_UNUSED(clk_gpmi);
Q_UNUSED(clk_h);
}
static TmplAnalyserFactory< ClockAnalyser > g_clock_factory(true, "Clock Analyser");
/**
* EMI analyser
*/
EmiAnalyser::EmiAnalyser(const soc_desc::soc_ref_t& soc, IoBackend *backend)
:AnalyserEx(soc, backend)
{
m_display_mode = DisplayCycles;
m_group = new QGroupBox("EMI Analyser");
QVBoxLayout *layout = new QVBoxLayout;
m_group->setLayout(layout);
m_panel = new QToolBox;
m_display_selector = new QComboBox;
m_display_selector->addItem("Cycles", DisplayCycles);
m_display_selector->addItem("Raw Hexadecimal", DisplayRawHex);
m_display_selector->addItem("Time", DisplayTime);
QHBoxLayout *line_layout = new QHBoxLayout;
line_layout->addWidget(new QLabel("Display Mode:"));
line_layout->addWidget(m_display_selector);
m_emi_freq_label = new QLineEdit;
m_emi_freq_label->setAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
m_emi_freq_label->setReadOnly(true);
m_emi_size_label = new QLineEdit;
m_emi_size_label->setAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
m_emi_size_label->setReadOnly(true);
line_layout->addStretch();
line_layout->addWidget(new QLabel("Size:"));
line_layout->addWidget(m_emi_size_label);
line_layout->addWidget(new QLabel("MiB"));
line_layout->addStretch();
line_layout->addWidget(new QLabel("Frequency:"));
line_layout->addWidget(m_emi_freq_label);
line_layout->addWidget(new QLabel("MHz"));
line_layout->addStretch();
layout->addLayout(line_layout);
layout->addWidget(m_panel);
connect(m_display_selector, SIGNAL(currentIndexChanged(int)), this,
SLOT(OnChangeDisplayMode(int)));
FillTable();
}
EmiAnalyser::~EmiAnalyser()
{
delete m_group;
}
QWidget *EmiAnalyser::GetWidget()
{
return m_group;
}
bool EmiAnalyser::SupportSoc(const QString& soc_name)
{
return soc_name == "imx233" || soc_name == "stmp3700";
}
void EmiAnalyser::OnChangeDisplayMode(int index)
{
if(index == -1)
return;
m_display_mode = (DisplayMode)m_display_selector->itemData(index).toInt();
int idx = m_panel->currentIndex();
FillTable();
m_panel->setCurrentIndex(idx);
}
void EmiAnalyser::NewGroup(const QString& name)
{
QTableWidget *table = new QTableWidget;
table->setColumnCount(3);
table->setHorizontalHeaderItem(0, new QTableWidgetItem("Name"));
table->setHorizontalHeaderItem(1, new QTableWidgetItem("Value"));
table->setHorizontalHeaderItem(2, new QTableWidgetItem("Comment"));
table->verticalHeader()->setVisible(false);
table->horizontalHeader()->setStretchLastSection(true);
m_panel->addItem(table, name);
}
void EmiAnalyser::AddLine(const QString& name, int value, const QString& unit, const QString& comment)
{
QTableWidget *table = dynamic_cast< QTableWidget* >(m_panel->widget(m_panel->count() - 1));
int row = table->rowCount();
table->setRowCount(row + 1);
table->setItem(row, 0, new QTableWidgetItem(name));
QString val;
if(value == INVALID)
val = "<invalid>";
else if(value == NONE)
val = unit;
else if(m_display_mode == DisplayRawHex && unit.size() == 0)
val = QString("0x%1").arg(value, 0, 16);
else
val = QString("%1%2").arg(value).arg(unit);
table->setItem(row, 1, new QTableWidgetItem(val));
table->item(row, 1)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
table->setItem(row, 2, new QTableWidgetItem(comment));
table->resizeColumnToContents(0);
table->resizeColumnToContents(1);
}
void EmiAnalyser::AddCycleLine(const QString& name, unsigned raw_val, float val,
int digits, const QString& comment)
{
if(m_display_mode == DisplayCycles)
{
QString str;
if(digits == 0)
str = QString("%1").arg((int)val);
else
str = QString("%1").arg(val, 0, 'f', digits);
str += " cycles";
AddLine(name, NONE, str, comment);
}
else if(m_display_mode == DisplayRawHex)
{
QString str = QString("0x%1").arg(raw_val, 0, 16);
AddLine(name, NONE, str, comment);
}
else if(m_display_mode == DisplayTime && m_emi_freq != 0)
{
float cycle_time_ns = 1000000000.0 / m_emi_freq;
val *= cycle_time_ns;
QString str;
if(val >= 1000)
str = QString::fromWCharArray(L"%1 µs").arg(val / 1000.0, 0, 'f', 2);
else
str = QString("%1 ns").arg(val, 0, 'f', 2);
AddLine(name, NONE, str, comment);
}
else
AddLine(name, raw_val, " cycles", comment);
}
void EmiAnalyser::FillTable()
{
while(m_panel->count() > 0)
m_panel->removeItem(0);
soc_word_t value;
m_emi_freq = 0;
if(ReadFieldOld("CLKCTRL", "CLKSEQ", "BYPASS_EMI", value))
{
bool ret;
if(value)
{
m_emi_freq = 24000000;
ret = ReadFieldOld("CLKCTRL", "EMI", "DIV_XTAL", value);
}
else
{
m_emi_freq = 480000000;
if(ReadFieldOld("CLKCTRL", "FRAC", "EMIFRAC", value))
m_emi_freq = 18 * (int64_t)m_emi_freq / value;
else
m_emi_freq = 0;
ret = ReadFieldOld("CLKCTRL", "EMI", "DIV_EMI", value);
}
if(ret)
m_emi_freq /= value;
else
m_emi_freq = 0;
}
m_emi_freq_label->setText(QString().sprintf("%.3f", m_emi_freq / 1000000.0));
soc_word_t rows, columns, cs_map;
if(ReadFieldOld("DRAM", "CTL14", "CS_MAP", cs_map) &&
ReadFieldOld("DRAM", "CTL10", "ADDR_PINS", rows) &&
ReadFieldOld("DRAM", "CTL11", "COLUMN_SIZE", columns))
{
rows = 13 - rows;
columns = 12 - columns;
soc_word_t banks = 4;
soc_word_t chips = __builtin_popcount(cs_map);
unsigned long size = 2 * (1 << (rows + columns)) * chips * banks;
m_emi_size_label->setText(QString().sprintf("%lu", (unsigned long)size / 1024 / 1024));
}
else
m_emi_size_label->setText("<invalid>");
NewGroup("Control Parameters");
if(ReadFieldOld("EMI", "CTRL", "PORT_PRIORITY_ORDER", value))
{
QStringList ports;
ports << "AXI0" << "AHB1" << "AHB2" << "AHB3";
QString order;
order += ports[value / 6];
ports.erase(ports.begin() + value / 6);
int ord[6][3] = { {0, 1, 2}, {2, 0, 1}, {1, 2, 0}, {2, 1, 0}, {1, 0, 2}, {0, 2, 1} };
for(int i = 0; i < 3; i++)
order += ", " + ports[ord[value % 6][i]];
AddLine("Port Priority Order", value, "", order);
}
if(ReadFieldOld("EMI", "CTRL", "MEM_WIDTH", value))
AddLine("Memory Width", value ? 16 : 8, "-bit");
if(ReadFieldOld("DRAM", "CTL03", "AP", value))
AddLine("Auto Pre-Charge", NONE, value ? "Yes" : "No");
bool bypass_mode = false;
if(ReadFieldOld("DRAM", "CTL04", "DLL_BYPASS_MODE", value))
{
bypass_mode = value == 1;
AddLine("DLL Bypass Mode", NONE, value ? "Yes" : "No");
}
if(ReadFieldOld("DRAM", "CTL05", "EN_LOWPOWER_MODE", value))
AddLine("Low Power Mode", NONE, value ? "Enabled" : "Disabled");
if(ReadFieldOld("DRAM", "CTL08", "SREFRESH", value))
AddLine("Self Refresh", NONE, value ? "Yes" : "No");
if(ReadFieldOld("DRAM", "CTL08", "SDR_MODE", value))
AddLine("Mode", NONE, value ? "SDR" : "DDR");
if(ReadFieldOld("DRAM", "CTL10", "ADDR_PINS", value))
AddLine("Address Pins", 13 - value, "");
if(ReadFieldOld("DRAM", "CTL11", "COLUMN_SIZE", value))
AddLine("Column Size", 12 - value, "-bit");
if(ReadFieldOld("DRAM", "CTL11", "CASLAT", value))
AddLine("Encoded CAS", value, "", "Memory device dependent");
if(ReadFieldOld("DRAM", "CTL14", "CS_MAP", value))
{
QString v;
for(int i = 0; i < 4; i++)
if(value & (1 << i))
{
if(v.size() != 0)
v += " ";
v += QString("%1").arg(i);
}
AddLine("Chip Select Pins", NONE, v, "");
}
if(ReadFieldOld("DRAM", "CTL37", "TREF_ENABLE", value))
AddLine("Refresh Commands", NONE, value ? "Enabled" : "Disabled", "Issue self-refresh every TREF cycles");
NewGroup("Frequency Parameters");
if(ReadFieldOld("DRAM", "CTL13", "CASLAT_LIN_GATE", value))
{
if(value >= 3 && value <= 10 && value != 9)
{
float v = (value / 2) + 0.5 * (value % 2);
AddCycleLine("CAS Gate", value, v, 1, "");
}
else
AddLine("CAS Gate", NONE, "Reserved", "Reserved value");
}
if(ReadFieldOld("DRAM", "CTL13", "CASLAT_LIN", value))
{
if(value >= 3 && value <= 10 && value != 9)
{
float v = (value / 2) + 0.5 * (value % 2);
AddCycleLine("CAS Latency", value, v, 1, "");
}
else
AddLine("CAS Latency", NONE, "Reserved", "Reserved value");
}
if(ReadFieldOld("DRAM", "CTL12", "TCKE", value))
AddCycleLine("tCKE", value, value, 0, "Minimum CKE pulse width");
if(ReadFieldOld("DRAM", "CTL15", "TDAL", value))
AddCycleLine("tDAL", value, value, 0, "Auto pre-charge write recovery time");
if(ReadFieldOld("DRAM", "CTL31", "TDLL", value))
AddCycleLine("tDLL", value, value, 0, "DLL lock time");
if(ReadFieldOld("DRAM", "CTL10", "TEMRS", value))
AddCycleLine("tEMRS", value, value, 0, "Extended mode parameter set time");
if(ReadFieldOld("DRAM", "CTL34", "TINIT", value))
AddCycleLine("tINIT", value, value, 0, "Initialisation time");
if(ReadFieldOld("DRAM", "CTL16", "TMRD", value))
AddCycleLine("tMRD", value, value, 0, "Mode register set command time");
if(ReadFieldOld("DRAM", "CTL40", "TPDEX", value))
AddCycleLine("tPDEX", value, value, 0, "Power down exit time");
if(ReadFieldOld("DRAM", "CTL32", "TRAS_MAX", value))
AddCycleLine("tRAS Max", value, value, 0, "Maximum row activate time");
if(ReadFieldOld("DRAM", "CTL20", "TRAS_MIN", value))
AddCycleLine("tRAS Min", value, value, 0, "Minimum row activate time");
if(ReadFieldOld("DRAM", "CTL17", "TRC", value))
AddCycleLine("tRC", value, value, 0, "Activate to activate delay (same bank)");
if(ReadFieldOld("DRAM", "CTL20", "TRCD_INT", value))
AddCycleLine("tRCD", value, value, 0, "RAS to CAS");
if(ReadFieldOld("DRAM", "CTL26", "TREF", value))
AddCycleLine("tREF", value, value, 0, "Refresh to refresh time");
if(ReadFieldOld("DRAM", "CTL21", "TRFC", value))
AddCycleLine("tRFC", value, value, 0, "Refresh command time");
if(ReadFieldOld("DRAM", "CTL15", "TRP", value))
AddCycleLine("tRP", value, value, 0, "Pre-charge command time");
if(ReadFieldOld("DRAM", "CTL12", "TRRD", value))
AddCycleLine("tRRD", value, value, 0, "Activate to activate delay (different banks)");
if(ReadFieldOld("DRAM", "CTL12", "TWR_INT", value))
AddCycleLine("tWR", value, value, 0, "Write recovery time");
if(ReadFieldOld("DRAM", "CTL13", "TWTR", value))
AddCycleLine("tWTR", value, value, 0, "Write to read delay");
if(ReadFieldOld("DRAM", "CTL32", "TXSNR", value))
AddCycleLine("tXSNR", value, value, 0, "");
if(ReadFieldOld("DRAM", "CTL33", "TXSR", value))
AddCycleLine("tXSR", value, value, 0, "Self-refresh exit time");
NewGroup("DLL Parameters");
if(bypass_mode)
{
if(ReadFieldOld("DRAM", "CTL19", "DLL_DQS_DELAY_BYPASS_0", value))
AddLine("DLL DQS Delay 0", value, "", "In 1/128 fraction of a cycle (bypass mode)");
if(ReadFieldOld("DRAM", "CTL19", "DLL_DQS_DELAY_BYPASS_0", value))
AddLine("DLL DQS Delay 1", value, "", "In 1/128 fraction of a cycle (bypass mode)");
if(ReadFieldOld("DRAM", "CTL19", "DQS_OUT_SHIFT_BYPASS", value))
AddLine("DQS Out Delay", value, "", "(bypass mode)");
if(ReadFieldOld("DRAM", "CTL20", "WR_DQS_SHIFT_BYPASS", value))
AddLine("DQS Write Delay", value, "", "(bypass mode)");
}
else
{
if(ReadFieldOld("DRAM", "CTL17", "DLL_START_POINT", value))
AddLine("DLL Start Point", value, "", "Initial delay count");
if(ReadFieldOld("DRAM", "CTL17", "DLL_INCREMENT", value))
AddLine("DLL Increment", value, "", "Delay increment");
if(ReadFieldOld("DRAM", "CTL18", "DLL_DQS_DELAY_0", value))
AddLine("DLL DQS Delay 0", value, "", "In 1/128 fraction of a cycle");
if(ReadFieldOld("DRAM", "CTL18", "DLL_DQS_DELAY_1", value))
AddLine("DLL DQS Delay 1", value, "", "In 1/128 fraction of a cycle");
if(ReadFieldOld("DRAM", "CTL19", "DQS_OUT_SHIFT", value))
AddLine("DQS Out Delay", value, "", "");
if(ReadFieldOld("DRAM", "CTL20", "WR_DQS_SHIFT", value))
AddLine("DQS Write Delay", value, "", "");
}
}
static TmplAnalyserFactory< EmiAnalyser > g_emi_factory(true, "EMI Analyser");
/**
* Pin analyser
*/
namespace pin_desc
{
#include "../../imxtools/misc/map.h"
}
PinAnalyser::PinAnalyser(const soc_desc::soc_ref_t& soc, IoBackend *backend)
:AnalyserEx(soc, backend)
{
m_group = new QGroupBox("Pin Analyser");
QVBoxLayout *layout = new QVBoxLayout;
m_group->setLayout(layout);
QLabel *label = new QLabel("Package:");
m_package_edit = new QLineEdit;
m_package_edit->setReadOnly(true);
m_package_edit->setAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
QHBoxLayout *hlayout = new QHBoxLayout;
hlayout->addStretch();
hlayout->addWidget(label);
hlayout->addWidget(m_package_edit);
hlayout->addStretch();
layout->addLayout(hlayout);
m_panel = new QToolBox;
layout->addWidget(m_panel);
FillList();
}
PinAnalyser::~PinAnalyser()
{
delete m_group;
}
QWidget *PinAnalyser::GetWidget()
{
return m_group;
}
bool PinAnalyser::SupportSoc(const QString& soc_name)
{
return soc_name == "imx233" || soc_name == "stmp3700";
}
void PinAnalyser::FillList()
{
soc_word_t value;
while(m_panel->count() > 0)
m_panel->removeItem(0);
const char *package_type[8] =
{
"bga169", "bga100", "lqfp100", "lqfp128", 0, 0, 0, 0
};
if(!ReadFieldOld("DIGCTL", "STATUS", "PACKAGE_TYPE", value))
{
m_package_edit->setText("<read error>");
return;
}
if(value >= 8 || package_type[value] == NULL)
{
m_package_edit->setText("<unknown package>");
return;
}
const char *package = package_type[value];
m_package_edit->setText(package);
pin_desc::bank_map_t *map = NULL;
for(size_t i = 0; i < sizeof(pin_desc::socs) / sizeof(pin_desc::socs[0]); i++)
if(QString(pin_desc::socs[i].soc) == m_io_backend->GetSocName() &&
QString(pin_desc::socs[i].ver) == package)
map = pin_desc::socs[i].map;
if(map == NULL)
{
m_package_edit->setText(QString("%1 (no map available)").arg(package));
return;
}
QMap< unsigned, QColor > color_map;
color_map[PIN_GROUP_EMI] = QColor(255, 255, 64);
color_map[PIN_GROUP_GPIO] = QColor(171, 214, 230);
color_map[PIN_GROUP_I2C] = QColor(191, 191, 255);
color_map[PIN_GROUP_JTAG] = QColor(238, 75, 21);
color_map[PIN_GROUP_PWM] = QColor(255, 236, 179);
color_map[PIN_GROUP_SPDIF] = QColor(174, 235, 63);
color_map[PIN_GROUP_TIMROT] = QColor(255, 112, 237);
color_map[PIN_GROUP_AUART] = QColor(94, 255, 128);
color_map[PIN_GROUP_ETM] = QColor(168, 53, 14);
color_map[PIN_GROUP_GPMI] = QColor(255, 211, 147);
color_map[PIN_GROUP_IrDA] = QColor(64, 97, 255);
color_map[PIN_GROUP_LCD] = QColor(124, 255, 255);
color_map[PIN_GROUP_SAIF] = QColor(255, 158, 158);
color_map[PIN_GROUP_SSP] = QColor(222, 128, 255);
color_map[PIN_GROUP_DUART] = QColor(192, 191, 191);
color_map[PIN_GROUP_USB] = QColor(0, 255, 0);
color_map[PIN_GROUP_NONE] = QColor(255, 255, 255);
for(int bank = 0; bank < 4; bank++)
{
QTableWidget *table = new QTableWidget;
table->setColumnCount(7);
table->setHorizontalHeaderItem(0, new QTableWidgetItem("Pin"));
table->setHorizontalHeaderItem(1, new QTableWidgetItem("Function"));
table->setHorizontalHeaderItem(2, new QTableWidgetItem("Direction"));
table->setHorizontalHeaderItem(3, new QTableWidgetItem("Drive"));
table->setHorizontalHeaderItem(4, new QTableWidgetItem("Voltage"));
table->setHorizontalHeaderItem(5, new QTableWidgetItem("Pull"));
table->setHorizontalHeaderItem(6, new QTableWidgetItem("Value"));
table->verticalHeader()->setVisible(false);
table->horizontalHeader()->setStretchLastSection(true);
m_panel->addItem(table, QString("Bank %1").arg(bank));
uint32_t muxsel[2], drive[4], pull, in, out, oe;
bool error = false;
for(int i = 0; i < 2; i++)
if(!ReadRegisterOld("PINCTRL", QString("MUXSELn[%1]").arg(bank * 2 + i), muxsel[i]))
error = true;
/* don't make an error for those since some do not exist */
for(int i = 0; i < 4; i++)
if(!ReadRegisterOld("PINCTRL", QString("DRIVEn[%1]").arg(bank * 4 + i), drive[i]))
drive[i] = 0;
if(error)
continue;
if(!ReadRegisterOld("PINCTRL", QString("PULLn[%1]").arg(bank), pull))
pull = 0;
if(!ReadRegisterOld("PINCTRL", QString("DINn[%1]").arg(bank), in))
in = 0;
if(!ReadRegisterOld("PINCTRL", QString("DOUTn[%1]").arg(bank), out))
out = 0;
if(!ReadRegisterOld("PINCTRL", QString("DOEn[%1]").arg(bank), oe))
oe = 0;
for(int pin = 0; pin < 32; pin++)
{
/* skip all-reserved pins */
bool all_dis = true;
for(int fn = 0; fn < 4; fn++)
if(map[bank].pins[pin].function[fn].name != NULL)
all_dis = false;
if(all_dis)
continue;
/* add line */
int row = table->rowCount();
table->setRowCount(row + 1);
/* name */
table->setItem(row, 0, new QTableWidgetItem(QString("B%1P%2")
.arg(bank).arg(pin, 2, 10, QChar('0'))));
table->item(row, 0)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* function */
int fn = (muxsel[pin / 16] >> ((pin % 16) * 2)) & 3;
table->setItem(row, 1, new QTableWidgetItem(QString(map[bank].pins[pin].function[fn].name)));
table->item(row, 1)->setBackground(QBrush(color_map[map[bank].pins[pin].function[fn].group]));
table->item(row, 1)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* direction */
table->setItem(row, 2, new QTableWidgetItem(fn != 3 ? "" : (oe & (1 << pin)) ? "Output" : "Input"));
table->item(row, 2)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* drive */
int drv = (drive[pin / 8] >> ((pin % 8) * 4)) & 3;
const char *strength[4] = {"4 mA", "8 mA", "12 mA", "16 mA"};
table->setItem(row, 3, new QTableWidgetItem(QString(strength[drv])));
table->item(row, 3)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* voltage */
int volt = (drive[pin / 8] >> (((pin % 8) * 4) + 2)) & 1;
if(m_io_backend->GetSocName() == "imx233")
volt = 1; /* cannot change voltage on imx233 */
const char *voltage[2] = {"1.8 V", "3.3 V"};
table->setItem(row, 4, new QTableWidgetItem(QString(voltage[volt])));
table->item(row, 4)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* pull */
table->setItem(row, 5, new QTableWidgetItem(QString("%1").arg((pull >> pin) & 1)));
table->item(row, 5)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
/* input */
table->setItem(row, 6, new QTableWidgetItem(QString("%1").arg((in >> pin) & 1)));
table->item(row, 6)->setTextAlignment(Qt::AlignHCenter | Qt::AlignVCenter);
}
}
}
static TmplAnalyserFactory< PinAnalyser > g_pin_factory(true, "Pin Analyser");