Difference between revisions of "MBC1"

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__TOC__
 
__TOC__
  
Nintendo's MBC2 can be used to address up to 2 Mbit of ROM and has 512×4 bit of internal RAM.
+
Nintendo's MBC1 can be used to address up to 16 Mbit of ROM and 256 kbit of SRAM, depending on the mode MBC1 is set to.
  
 
= Pinout =
 
= Pinout =
  
[[Image:MBC2 Pinout.png|center|x300px]]
+
[[Image:MBC1 Pinout.png|center|x300px]]
  
 
{| class="wikitable pintable" style="margin:1em auto; width: 66%;"
 
{| class="wikitable pintable" style="margin:1em auto; width: 66%;"
Line 13: Line 13:
 
!style="width: 60%;" | Comment
 
!style="width: 60%;" | Comment
 
|-
 
|-
|28
+
|24
 
|VCC
 
|VCC
 
|PWR
 
|PWR
|I/O 5V supply
+
|5V supply
 
|-
 
|-
|14
+
|12
 
|GND
 
|GND
 
|PWR
 
|PWR
|I/O Ground supply
+
|Ground supply
 
|-
 
|-
|21
+
|5–1
|VCC_RAM
+
|D4–D0
|PWR
+
|I
|RAM supply
 
|-
 
|7
 
|GND_RAM
 
|PWR
 
|RAM Ground supply
 
|-
 
|12{{ndash}}9
 
|D3{{ndash}}D0
 
|I/O
 
 
|Data Bus
 
|Data Bus
 
|-
 
|-
|1
+
|11
 
|{{Overline|RD}}
 
|{{Overline|RD}}
 
|I
 
|I
 
|Low-Active Read Enable
 
|Low-Active Read Enable
 
|-
 
|-
|27
+
|22
 
|{{Overline|WR}}
 
|{{Overline|WR}}
 
|I
 
|I
 
|Low-Active Write Enable
 
|Low-Active Write Enable
 
|-
 
|-
|26
+
|23
 
|{{Overline|CS}}
 
|{{Overline|CS}}
 
|I
 
|I
 
|Low-Active Chip Select
 
|Low-Active Chip Select
 
|-
 
|-
|15
+
|10
 
|{{Overline|RESET}}
 
|{{Overline|RESET}}
 
|I
 
|I
 
|Low-Active Asynchronous Reset
 
|Low-Active Asynchronous Reset
 
|-
 
|-
|20, 22, 23{{ndash}}25, 8, 6{{ndash}}2
+
|21–19
|A15{{ndash}}A14, A8{{ndash}}A0
+
|A15–A13
 
|I
 
|I
 
|Address Bus
 
|Address Bus
 
|-
 
|-
|16{{ndash}}19
+
|18–14
|RA17{{ndash}}RA14
+
|RA18–RA14
 
|O
 
|O
 
|Upper ROM Address Lines
 
|Upper ROM Address Lines
 +
|-
 +
|7–6
 +
|AA14–AA13
 +
|O
 +
|Upper ROM/RAM Address Lines
 +
|-
 +
|8
 +
|{{Overline|RAM_CS}}
 +
|O
 +
|Low-Active RAM Chip Select
 +
|-
 +
|9
 +
|RAM_CS
 +
|O
 +
|High-Active RAM Chip Select
 
|-
 
|-
 
|13
 
|13
Line 74: Line 79:
 
|}
 
|}
  
Footprint: SOP127P1200X225-28
+
Footprint: SOP127P1200X225-24
 
 
Remarks: All I/Os have diode protection against VCC/GND. Internal RAM is supplied by VCC as well as VCC_RAM, probably depending on the VCC voltage.
 
  
 
{{clear|both}}
 
{{clear|both}}
Line 85: Line 88:
 
Write-Accessible Registers:
 
Write-Accessible Registers:
  
* <tt>0b00-- ---0 ---- ----</tt>: RAM Enable register
+
* <tt>0x0000-0x1FFF</tt>: RAM Enable register
* <tt>0b00-- ---1 ---- ----</tt>: ROM Bank register
+
* <tt>0x2000-0x3FFF</tt>: ROM Bank register
* <tt>0b10-- ---a aaaa aaaa</tt>: Internal RAM
+
* <tt>0x4000-0x5FFF</tt>: RAM Bank register
 +
* <tt>0x6000-0x7FFF</tt>: Mode register
  
 
== RAM Enable Register ==
 
== RAM Enable Register ==
Line 103: Line 107:
  
 
<pre>
 
<pre>
XX XX XX XX D3 D2 D1 D0    0x00 @ reset
+
XX XX XX D4 D3 D2 D1 D0    0x00 @ reset
            \_________/
+
        \____________/
 
                 \-------- ROM Bank
 
                 \-------- ROM Bank
  
 
</pre>
 
</pre>
  
ROM Bank selects which bank is mapped to 0x4000-0x7FFF. The written value is zero-adjusted before output on RA17{{ndash}}RA14.
+
ROM Bank selects which bank is mapped to 0x4000-0x7FFF. The written value is zero-adjusted before output on RA18&ndash;RA14.
 +
 
 +
== RAM Bank Register ==
 +
 
 +
<pre>
 +
XX XX XX XX XX XX D1 D0    0x00 @ reset
 +
                  \___/
 +
                    \----- RAM Bank
 +
 
 +
</pre>
 +
 
 +
RAM Bank selects which bank is mapped to 0xA000-0xBFFF when in mode 4&nbsp;MBit/256&nbsp;kbit. When in mode 16&nbsp;Mbit/64&nbsp;kbit, it can be used to select the upper two ROM address lines.
 +
 
 +
== Mode Register ==
 +
 
 +
<pre>
 +
XX XX XX XX XX XX XX D0    0x00 @ reset
 +
                      |
 +
                      \--- Mode
 +
 
 +
</pre>
 +
 
 +
The mode bit switches between 16&nbsp;Mbit ROM/64&nbsp;kbit SRAM mode ('0') and 4&nbsp;Mbit ROM/256&nbsp;kbit SRAM mode ('1'). When in 16&nbsp;Mbit/64&nbsp;kbit mode, address lines AA14&ndash;AA13 switch according to A14. When in 4&nbsp;Mbit/256&nbsp;kbit mode, the upper address lines AA14&ndash;AA13 stay fixed regardless of A14.
  
 
= Behavior =
 
= Behavior =
  
 
<source lang="vhdl">
 
<source lang="vhdl">
TODO
+
library IEEE;
 +
use IEEE.std_logic_1164.all;
 +
 
 +
entity MBC1 is
 +
Port(
 +
RESET_N  : in  std_logic;
 +
RD_N    : in  std_logic;
 +
WR_N    : in  std_logic;
 +
CS_N    : in  std_logic;
 +
A        : in  std_logic_vector(15 downto 13);
 +
D        : in  std_logic_vector(4 downto 0);
 +
RA      : out std_logic_vector(18 downto 14);
 +
AA      : out std_logic_vector(14 downto 13);
 +
ROM_CS_N : out std_logic;
 +
RAM_CS_N : out std_logic;
 +
RAM_CS  : out std_logic
 +
);
 +
end entity MBC1;
 +
 
 +
architecture Behavioral of MBC1 is
 +
 +
signal ram_enable_r : std_logic_vector(3 downto 0);
 +
signal rom_bank_r  : std_logic_vector(4 downto 0);
 +
signal ram_bank_r  : std_logic_vector(1 downto 0);
 +
signal mode_r      : std_logic_vector(0 downto 0);
 +
 
 +
signal ram_enable_r_clk : std_logic;
 +
signal rom_bank_r_clk  : std_logic;
 +
signal ram_bank_r_clk  : std_logic;
 +
signal mode_r_clk      : std_logic;
 +
 
 +
begin
 +
 
 +
-----------------------------------------------------------------------
 +
-- Signal Assignments
 +
-----------------------------------------------------------------------
 +
 
 +
ROM_CS_N <= '0' when ((A(15) = '0' and RD_N = '0') or RESET_N = '0') else
 +
            '1';
 +
 
 +
RAM_CS_N <= '0' when (CS_N = '0' and A(14) = '0' and ram_enable_r = x"A") else
 +
            '1';
 +
RAM_CS <= not RAM_CS_N;
 +
 
 +
RA(18 downto 14) <= "00000"    when (A(14) = '0' or RESET_N = '0') else
 +
                    rom_bank_r when (rom_bank_r /= "00000") else
 +
                    "00001";
 +
 
 +
AA(14 downto 13) <= "00" when (A(14) = '0' and mode_r = "0") else
 +
                    ram_bank_r;
 +
 
 +
ram_enable_r_clk <= '0' when (A = "000" and WR_N = '0') else
 +
                    '1';
 +
 
 +
rom_bank_r_clk <= '0' when (A = "001" and WR_N = '0') else
 +
                  '1';
 +
 
 +
ram_bank_r_clk <= '0' when (A = "010" and WR_N = '0') else
 +
                  '1';
 +
 
 +
mode_r_clk <= '0' when (A = "011" and WR_N = '0') else
 +
              '1';
 +
 
 +
-----------------------------------------------------------------------
 +
-- Registers
 +
-----------------------------------------------------------------------
 +
 
 +
ram_enable_p : process (
 +
RESET_N,
 +
ram_enable_r_clk
 +
)
 +
begin
 +
 
 +
if (RESET_N = '0') then
 +
 +
ram_enable_r <= x"0";
 +
 +
elsif (rising_edge(ram_enable_r_clk)) then
 +
 +
ram_enable_r <= D(3 downto 0);
 +
 +
end if;
 +
 
 +
end process ram_enable_p;
 +
 
 +
rom_bank_p : process (
 +
RESET_N,
 +
rom_bank_r_clk
 +
)
 +
begin
 +
 
 +
if (RESET_N = '0') then
 +
 +
rom_bank_r <= "00000";
 +
 +
elsif (rising_edge(rom_bank_r_clk)) then
 +
 +
rom_bank_r <= D;
 +
 +
end if;
 +
 +
end process rom_bank_p;
 +
 
 +
ram_bank_p : process (
 +
RESET_N,
 +
ram_bank_r_clk
 +
)
 +
begin
 +
 
 +
if (RESET_N = '0') then
 +
 +
ram_bank_r <= "00";
 +
 +
elsif (rising_edge(ram_bank_r_clk)) then
 +
 +
ram_bank_r <= D(1 downto 0);
 +
 +
end if;
 +
 +
end process ram_bank_p;
 +
 
 +
mode_p : process (
 +
RESET_N,
 +
mode_r_clk
 +
)
 +
begin
 +
 
 +
if (RESET_N = '0') then
 +
 +
mode_r <= "0";
 +
 +
elsif (rising_edge(mode_r_clk)) then
 +
 +
mode_r <= D(0 downto 0);
 +
 +
end if;
 +
 
 +
end process mode_p;
 +
 
 +
end architecture Behavioral;
 
</source>
 
</source>
 +
 +
[[Category:DMG]]

Latest revision as of 21:30, 23 June 2017

Nintendo's MBC1 can be used to address up to 16 Mbit of ROM and 256 kbit of SRAM, depending on the mode MBC1 is set to.

Pinout

MBC1 Pinout.png
Pin No. Name Type Comment
24 VCC PWR 5V supply
12 GND PWR Ground supply
5–1 D4–D0 I Data Bus
11 RD I Low-Active Read Enable
22 WR I Low-Active Write Enable
23 CS I Low-Active Chip Select
10 RESET I Low-Active Asynchronous Reset
21–19 A15–A13 I Address Bus
18–14 RA18–RA14 O Upper ROM Address Lines
7–6 AA14–AA13 O Upper ROM/RAM Address Lines
8 RAM_CS O Low-Active RAM Chip Select
9 RAM_CS O High-Active RAM Chip Select
13 ROM_CS O Low-Active ROM Chip Select

Footprint: SOP127P1200X225-24

Registers

Write-Accessible Registers:

  • 0x0000-0x1FFF: RAM Enable register
  • 0x2000-0x3FFF: ROM Bank register
  • 0x4000-0x5FFF: RAM Bank register
  • 0x6000-0x7FFF: Mode register

RAM Enable Register

XX XX XX XX D3 D2 D1 D0    0x00 @ reset
            \_________/
                 \-------- RAM Enable

A value of 0x0A enables SRAM access, all other values disable SRAM access.

ROM Bank Register

XX XX XX D4 D3 D2 D1 D0    0x00 @ reset
         \____________/
                 \-------- ROM Bank

ROM Bank selects which bank is mapped to 0x4000-0x7FFF. The written value is zero-adjusted before output on RA18–RA14.

RAM Bank Register

XX XX XX XX XX XX D1 D0    0x00 @ reset
                  \___/
                    \----- RAM Bank

RAM Bank selects which bank is mapped to 0xA000-0xBFFF when in mode 4 MBit/256 kbit. When in mode 16 Mbit/64 kbit, it can be used to select the upper two ROM address lines.

Mode Register

XX XX XX XX XX XX XX D0    0x00 @ reset
                      |
                      \--- Mode

The mode bit switches between 16 Mbit ROM/64 kbit SRAM mode ('0') and 4 Mbit ROM/256 kbit SRAM mode ('1'). When in 16 Mbit/64 kbit mode, address lines AA14–AA13 switch according to A14. When in 4 Mbit/256 kbit mode, the upper address lines AA14–AA13 stay fixed regardless of A14.

Behavior

library IEEE;
use IEEE.std_logic_1164.all;

entity MBC1 is
	Port(
		RESET_N  : in  std_logic;
		RD_N     : in  std_logic;
		WR_N     : in  std_logic;
		CS_N     : in  std_logic;
		A        : in  std_logic_vector(15 downto 13);
		D        : in  std_logic_vector(4 downto 0);
		RA       : out std_logic_vector(18 downto 14);
		AA       : out std_logic_vector(14 downto 13);
		ROM_CS_N : out std_logic;
		RAM_CS_N : out std_logic;
		RAM_CS   : out std_logic
	);
end entity MBC1;

architecture Behavioral of MBC1 is
	
signal ram_enable_r : std_logic_vector(3 downto 0);
signal rom_bank_r   : std_logic_vector(4 downto 0);
signal ram_bank_r   : std_logic_vector(1 downto 0);
signal mode_r       : std_logic_vector(0 downto 0);

signal ram_enable_r_clk : std_logic;
signal rom_bank_r_clk   : std_logic;
signal ram_bank_r_clk   : std_logic;
signal mode_r_clk       : std_logic;

begin

-----------------------------------------------------------------------
-- Signal Assignments
-----------------------------------------------------------------------

ROM_CS_N <= '0' when ((A(15) = '0' and RD_N = '0') or RESET_N = '0') else
            '1';

RAM_CS_N <= '0' when (CS_N = '0' and A(14) = '0' and ram_enable_r = x"A") else
            '1';
RAM_CS <= not RAM_CS_N;

RA(18 downto 14) <= "00000"    when (A(14) = '0' or RESET_N = '0') else
                    rom_bank_r when (rom_bank_r /= "00000") else
                    "00001";

AA(14 downto 13) <= "00" when (A(14) = '0' and mode_r = "0") else
                    ram_bank_r;

ram_enable_r_clk <= '0' when (A = "000" and WR_N = '0') else
                    '1';

rom_bank_r_clk <= '0' when (A = "001" and WR_N = '0') else
                  '1';

ram_bank_r_clk <= '0' when (A = "010" and WR_N = '0') else
                  '1';

mode_r_clk <= '0' when (A = "011" and WR_N = '0') else
              '1';

-----------------------------------------------------------------------
-- Registers
-----------------------------------------------------------------------

ram_enable_p : process (
	RESET_N,
	ram_enable_r_clk
	)
begin

	if (RESET_N = '0') then
	
		ram_enable_r <= x"0";
	
	elsif (rising_edge(ram_enable_r_clk)) then
	
		ram_enable_r <= D(3 downto 0);
	
	end if;

end process ram_enable_p;

rom_bank_p : process (
	RESET_N,
	rom_bank_r_clk
	)
begin

	if (RESET_N = '0') then
	
		rom_bank_r <= "00000";
	
	elsif (rising_edge(rom_bank_r_clk)) then
	
		rom_bank_r <= D;
	
	end if;
	
end process rom_bank_p;

ram_bank_p : process (
	RESET_N,
	ram_bank_r_clk
	)
begin

	if (RESET_N = '0') then
	
		ram_bank_r <= "00";
	
	elsif (rising_edge(ram_bank_r_clk)) then
	
		ram_bank_r <= D(1 downto 0);
	
	end if;
	
end process ram_bank_p;

mode_p : process (
	RESET_N,
	mode_r_clk
	)
begin

	if (RESET_N = '0') then
	
		mode_r <= "0";
	
	elsif (rising_edge(mode_r_clk)) then
	
		mode_r <= D(0 downto 0);
	
	end if;

end process mode_p;

end architecture Behavioral;